platform_build_soong/apex/apex.go

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// Copyright (C) 2018 The Android Open Source Project
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
// package apex implements build rules for creating the APEX files which are container for
// lower-level system components. See https://source.android.com/devices/tech/ota/apex
package apex
import (
"fmt"
"log"
"path/filepath"
"regexp"
"sort"
"strings"
"github.com/google/blueprint"
"github.com/google/blueprint/proptools"
"android/soong/android"
"android/soong/bpf"
"android/soong/cc"
prebuilt_etc "android/soong/etc"
"android/soong/filesystem"
"android/soong/java"
"android/soong/multitree"
"android/soong/rust"
"android/soong/sh"
)
func init() {
registerApexBuildComponents(android.InitRegistrationContext)
}
func registerApexBuildComponents(ctx android.RegistrationContext) {
ctx.RegisterModuleType("apex", BundleFactory)
ctx.RegisterModuleType("apex_test", TestApexBundleFactory)
ctx.RegisterModuleType("apex_vndk", vndkApexBundleFactory)
ctx.RegisterModuleType("apex_defaults", DefaultsFactory)
ctx.RegisterModuleType("prebuilt_apex", PrebuiltFactory)
ctx.RegisterModuleType("override_apex", OverrideApexFactory)
ctx.RegisterModuleType("apex_set", apexSetFactory)
ctx.PreArchMutators(registerPreArchMutators)
ctx.PreDepsMutators(RegisterPreDepsMutators)
ctx.PostDepsMutators(RegisterPostDepsMutators)
}
func registerPreArchMutators(ctx android.RegisterMutatorsContext) {
ctx.TopDown("prebuilt_apex_module_creator", prebuiltApexModuleCreatorMutator).Parallel()
}
func RegisterPreDepsMutators(ctx android.RegisterMutatorsContext) {
ctx.TopDown("apex_vndk", apexVndkMutator).Parallel()
ctx.BottomUp("apex_vndk_deps", apexVndkDepsMutator).Parallel()
}
func RegisterPostDepsMutators(ctx android.RegisterMutatorsContext) {
ctx.TopDown("apex_info", apexInfoMutator).Parallel()
ctx.BottomUp("apex_unique", apexUniqueVariationsMutator).Parallel()
ctx.BottomUp("apex_test_for_deps", apexTestForDepsMutator).Parallel()
ctx.BottomUp("apex_test_for", apexTestForMutator).Parallel()
// Run mark_platform_availability before the apexMutator as the apexMutator needs to know whether
// it should create a platform variant.
ctx.BottomUp("mark_platform_availability", markPlatformAvailability).Parallel()
ctx.BottomUp("apex", apexMutator).Parallel()
ctx.BottomUp("apex_directly_in_any", apexDirectlyInAnyMutator).Parallel()
ctx.BottomUp("apex_dcla_deps", apexDCLADepsMutator).Parallel()
// Register after apex_info mutator so that it can use ApexVariationName
ctx.TopDown("apex_strict_updatability_lint", apexStrictUpdatibilityLintMutator).Parallel()
}
apex_available tracks static dependencies This change fixes a bug that apex_available is not enforced for static dependencies. For example, a module with 'apex_available: ["//apex_available:platform"]' was able to be statically linked to any APEX. This was happening because the check was done on the modules that are actually installed to an APEX. Static dependencies of the modules were not counted as they are not installed to the APEX as files. Fixing this bug by doing the check by traversing the tree in the method checkApexAvailability. This change includes a few number of related changes: 1) DepIsInSameApex implementation for cc.Module was changed as well. Previuosly, it returned false only when the dependency is actually a stub variant of a lib. Now, it returns false when the dependency has one or more stub variants. To understand why, we need to recall that when there is a dependency to a lib having stubs, we actually create two dependencies: to the non-stub variant and to the stub variant during the DepsMutator phase. And later in the build action generation phase, we choose one of them depending on the context. Also recall that an APEX variant is created only when DepIsInSameApex returns true. Given these, with the previous implementatin of DepIsInSameApex, we did create apex variants of the non-stub variant of the dependency, while not creating the apex variant for the stub variant. This is not right; we needlessly created the apex variant. The extra apex variant has caused no harm so far, but since the apex_available check became more correct, it actually breaks the build. To fix the issue, we stop creating the APEX variant both for non-stub and stub variants. 2) platform variant is created regardless of the apex_available value. This is required for the case when a library X that provides stub is in an APEX A and is configured to be available only for A. In that case, libs in other APEX can't use the stub library since the stub library is mutated only for apex A. By creating the platform variant for the stub library, it can be used from outside as the default dependency variation is set to the platform variant when creating the APEX variations. 3) The ApexAvailableWhitelist is added with the dependencies that were revealed with this change. Exempt-From-Owner-Approval: cherry-pick from internal Bug: 147671264 Test: m Merged-In: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e (cherry picked from commit fa89944c79f19552e906b41fd03a4981903eee7e) Change-Id: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e
2020-01-30 18:49:53 +01:00
type apexBundleProperties struct {
// Json manifest file describing meta info of this APEX bundle. Refer to
// system/apex/proto/apex_manifest.proto for the schema. Default: "apex_manifest.json"
Manifest *string `android:"path"`
// AndroidManifest.xml file used for the zip container of this APEX bundle. If unspecified,
// a default one is automatically generated.
AndroidManifest *string `android:"path"`
// Determines the file contexts file for setting the security contexts to files in this APEX
// bundle. For platform APEXes, this should points to a file under /system/sepolicy Default:
// /system/sepolicy/apex/<module_name>_file_contexts.
File_contexts *string `android:"path"`
// By default, file_contexts is amended by force-labelling / and /apex_manifest.pb as system_file
// to avoid mistakes. When set as true, no force-labelling.
Use_file_contexts_as_is *bool
// Path to the canned fs config file for customizing file's
// uid/gid/mod/capabilities. The content of this file is appended to the
// default config, so that the custom entries are preferred. The format is
// /<path_or_glob> <uid> <gid> <mode> [capabilities=0x<cap>], where
// path_or_glob is a path or glob pattern for a file or set of files,
// uid/gid are numerial values of user ID and group ID, mode is octal value
// for the file mode, and cap is hexadecimal value for the capability.
Canned_fs_config *string `android:"path"`
ApexNativeDependencies
Multilib apexMultilibProperties
// List of runtime resource overlays (RROs) that are embedded inside this APEX.
Rros []string
// List of bootclasspath fragments that are embedded inside this APEX bundle.
Bootclasspath_fragments []string
// List of systemserverclasspath fragments that are embedded inside this APEX bundle.
Systemserverclasspath_fragments []string
// List of java libraries that are embedded inside this APEX bundle.
Java_libs []string
// List of sh binaries that are embedded inside this APEX bundle.
Sh_binaries []string
// List of platform_compat_config files that are embedded inside this APEX bundle.
Compat_configs []string
// List of filesystem images that are embedded inside this APEX bundle.
Filesystems []string
// List of module names which we don't want to add as transitive deps. This can be used as
// a workaround when the current implementation collects more than necessary. For example,
// Rust binaries with prefer_rlib:true add unnecessary dependencies.
Unwanted_transitive_deps []string
// The minimum SDK version that this APEX must support at minimum. This is usually set to
// the SDK version that the APEX was first introduced.
Min_sdk_version *string
// Whether this APEX is considered updatable or not. When set to true, this will enforce
// additional rules for making sure that the APEX is truly updatable. To be updatable,
// min_sdk_version should be set as well. This will also disable the size optimizations like
// symlinking to the system libs. Default is true.
Updatable *bool
// Marks that this APEX is designed to be updatable in the future, although it's not
// updatable yet. This is used to mimic some of the build behaviors that are applied only to
// updatable APEXes. Currently, this disables the size optimization, so that the size of
// APEX will not increase when the APEX is actually marked as truly updatable. Default is
// false.
Future_updatable *bool
// Whether this APEX can use platform APIs or not. Can be set to true only when `updatable:
// false`. Default is false.
Platform_apis *bool
// Whether this APEX is installable to one of the partitions like system, vendor, etc.
// Default: true.
Installable *bool
// If set true, VNDK libs are considered as stable libs and are not included in this APEX.
// Should be only used in non-system apexes (e.g. vendor: true). Default is false.
Use_vndk_as_stable *bool
// The type of filesystem to use. Either 'ext4', 'f2fs' or 'erofs'. Default 'ext4'.
Payload_fs_type *string
// For telling the APEX to ignore special handling for system libraries such as bionic.
// Default is false.
Ignore_system_library_special_case *bool
// Whenever apex_payload.img of the APEX should include dm-verity hashtree.
// Default value is true.
Generate_hashtree *bool
// Whenever apex_payload.img of the APEX should not be dm-verity signed. Should be only
// used in tests.
Test_only_unsigned_payload *bool
// Whenever apex should be compressed, regardless of product flag used. Should be only
// used in tests.
Test_only_force_compression *bool
// Put extra tags (signer=<value>) to apexkeys.txt, so that release tools can sign this apex
// with the tool to sign payload contents.
Custom_sign_tool *string
// Whether this is a dynamic common lib apex, if so the native shared libs will be placed
// in a special way that include the digest of the lib file under /lib(64)?
Dynamic_common_lib_apex *bool
// Canonical name of this APEX bundle. Used to determine the path to the
// activated APEX on device (i.e. /apex/<apexVariationName>), and used for the
// apex mutator variations. For override_apex modules, this is the name of the
// overridden base module.
ApexVariationName string `blueprint:"mutated"`
IsCoverageVariant bool `blueprint:"mutated"`
// List of sanitizer names that this APEX is enabled for
SanitizerNames []string `blueprint:"mutated"`
PreventInstall bool `blueprint:"mutated"`
HideFromMake bool `blueprint:"mutated"`
// Name that dependencies can specify in their apex_available properties to refer to this module.
// If not specified, this defaults to Soong module name. This must be the name of a Soong module.
Apex_available_name *string
// Variant version of the mainline module. Must be an integer between 0-9
Variant_version *string
}
type ApexNativeDependencies struct {
// List of native libraries that are embedded inside this APEX.
Native_shared_libs []string
// List of JNI libraries that are embedded inside this APEX.
Jni_libs []string
// List of rust dyn libraries that are embedded inside this APEX.
Rust_dyn_libs []string
// List of native executables that are embedded inside this APEX.
Binaries []string
// List of native tests that are embedded inside this APEX.
Tests []string
// List of filesystem images that are embedded inside this APEX bundle.
Filesystems []string
// List of native libraries to exclude from this APEX.
Exclude_native_shared_libs []string
// List of JNI libraries to exclude from this APEX.
Exclude_jni_libs []string
// List of rust dyn libraries to exclude from this APEX.
Exclude_rust_dyn_libs []string
// List of native executables to exclude from this APEX.
Exclude_binaries []string
// List of native tests to exclude from this APEX.
Exclude_tests []string
// List of filesystem images to exclude from this APEX bundle.
Exclude_filesystems []string
}
// Merge combines another ApexNativeDependencies into this one
func (a *ApexNativeDependencies) Merge(b ApexNativeDependencies) {
a.Native_shared_libs = append(a.Native_shared_libs, b.Native_shared_libs...)
a.Jni_libs = append(a.Jni_libs, b.Jni_libs...)
a.Rust_dyn_libs = append(a.Rust_dyn_libs, b.Rust_dyn_libs...)
a.Binaries = append(a.Binaries, b.Binaries...)
a.Tests = append(a.Tests, b.Tests...)
a.Filesystems = append(a.Filesystems, b.Filesystems...)
a.Exclude_native_shared_libs = append(a.Exclude_native_shared_libs, b.Exclude_native_shared_libs...)
a.Exclude_jni_libs = append(a.Exclude_jni_libs, b.Exclude_jni_libs...)
a.Exclude_rust_dyn_libs = append(a.Exclude_rust_dyn_libs, b.Exclude_rust_dyn_libs...)
a.Exclude_binaries = append(a.Exclude_binaries, b.Exclude_binaries...)
a.Exclude_tests = append(a.Exclude_tests, b.Exclude_tests...)
a.Exclude_filesystems = append(a.Exclude_filesystems, b.Exclude_filesystems...)
}
type apexMultilibProperties struct {
// Native dependencies whose compile_multilib is "first"
First ApexNativeDependencies
// Native dependencies whose compile_multilib is "both"
Both ApexNativeDependencies
// Native dependencies whose compile_multilib is "prefer32"
Prefer32 ApexNativeDependencies
// Native dependencies whose compile_multilib is "32"
Lib32 ApexNativeDependencies
// Native dependencies whose compile_multilib is "64"
Lib64 ApexNativeDependencies
}
type apexTargetBundleProperties struct {
Target struct {
// Multilib properties only for android.
Android struct {
Multilib apexMultilibProperties
}
// Multilib properties only for host.
Host struct {
Multilib apexMultilibProperties
}
// Multilib properties only for host linux_bionic.
Linux_bionic struct {
Multilib apexMultilibProperties
}
// Multilib properties only for host linux_glibc.
Linux_glibc struct {
Multilib apexMultilibProperties
}
}
}
type apexArchBundleProperties struct {
Arch struct {
Arm struct {
ApexNativeDependencies
}
Arm64 struct {
ApexNativeDependencies
}
Riscv64 struct {
ApexNativeDependencies
}
X86 struct {
ApexNativeDependencies
}
X86_64 struct {
ApexNativeDependencies
}
}
}
// These properties can be used in override_apex to override the corresponding properties in the
// base apex.
type overridableProperties struct {
// List of APKs that are embedded inside this APEX.
Apps []string
// List of prebuilt files that are embedded inside this APEX bundle.
Prebuilts []string
// List of BPF programs inside this APEX bundle.
Bpfs []string
// Names of modules to be overridden. Listed modules can only be other binaries (in Make or
// Soong). This does not completely prevent installation of the overridden binaries, but if
// both binaries would be installed by default (in PRODUCT_PACKAGES) the other binary will
// be removed from PRODUCT_PACKAGES.
Overrides []string
// Logging parent value.
Logging_parent string
// Apex Container package name. Override value for attribute package:name in
// AndroidManifest.xml
Package_name string
// A txt file containing list of files that are allowed to be included in this APEX.
Allowed_files *string `android:"path"`
// Name of the apex_key module that provides the private key to sign this APEX bundle.
Key *string
// Specifies the certificate and the private key to sign the zip container of this APEX. If
// this is "foo", foo.x509.pem and foo.pk8 under PRODUCT_DEFAULT_DEV_CERTIFICATE are used
// as the certificate and the private key, respectively. If this is ":module", then the
// certificate and the private key are provided from the android_app_certificate module
// named "module".
Certificate *string
// Whether this APEX can be compressed or not. Setting this property to false means this
// APEX will never be compressed. When set to true, APEX will be compressed if other
// conditions, e.g., target device needs to support APEX compression, are also fulfilled.
// Default: false.
Compressible *bool
// Trim against a specific Dynamic Common Lib APEX
Trim_against *string
}
type apexBundle struct {
// Inherited structs
android.ModuleBase
android.DefaultableModuleBase
android.OverridableModuleBase
multitree.ExportableModuleBase
// Properties
properties apexBundleProperties
targetProperties apexTargetBundleProperties
archProperties apexArchBundleProperties
overridableProperties overridableProperties
vndkProperties apexVndkProperties // only for apex_vndk modules
///////////////////////////////////////////////////////////////////////////////////////////
// Inputs
// Keys for apex_payload.img
publicKeyFile android.Path
privateKeyFile android.Path
// Cert/priv-key for the zip container
containerCertificateFile android.Path
containerPrivateKeyFile android.Path
// Flags for special variants of APEX
testApex bool
vndkApex bool
// File system type of apex_payload.img
payloadFsType fsType
// Whether to create symlink to the system file instead of having a file inside the apex or
// not
linkToSystemLib bool
// List of files to be included in this APEX. This is filled in the first part of
// GenerateAndroidBuildActions.
filesInfo []apexFile
// List of other module names that should be installed when this APEX gets installed (LOCAL_REQUIRED_MODULES).
makeModulesToInstall []string
///////////////////////////////////////////////////////////////////////////////////////////
// Outputs (final and intermediates)
// Processed apex manifest in JSONson format (for Q)
manifestJsonOut android.WritablePath
// Processed apex manifest in PB format (for R+)
manifestPbOut android.WritablePath
// Processed file_contexts files
fileContexts android.WritablePath
// The built APEX file. This is the main product.
// Could be .apex or .capex
outputFile android.WritablePath
// The built uncompressed .apex file.
outputApexFile android.WritablePath
// The built APEX file in app bundle format. This file is not directly installed to the
// device. For an APEX, multiple app bundles are created each of which is for a specific ABI
// like arm, arm64, x86, etc. Then they are processed again (outside of the Android build
// system) to be merged into a single app bundle file that Play accepts. See
// vendor/google/build/build_unbundled_mainline_module.sh for more detail.
bundleModuleFile android.WritablePath
// Target directory to install this APEX. Usually out/target/product/<device>/<partition>/apex.
installDir android.InstallPath
// Path where this APEX was installed.
installedFile android.InstallPath
// fragment for this apex for apexkeys.txt
apexKeysPath android.WritablePath
// Installed locations of symlinks for backward compatibility.
compatSymlinks android.InstallPaths
// Text file having the list of individual files that are included in this APEX. Used for
// debugging purpose.
installedFilesFile android.WritablePath
// List of module names that this APEX is including (to be shown via *-deps-info target).
// Used for debugging purpose.
android.ApexBundleDepsInfo
// Optional list of lint report zip files for apexes that contain java or app modules
lintReports android.Paths
isCompressed bool
// Path of API coverage generate file
nativeApisUsedByModuleFile android.ModuleOutPath
nativeApisBackedByModuleFile android.ModuleOutPath
javaApisUsedByModuleFile android.ModuleOutPath
aconfigFiles []android.Path
}
// apexFileClass represents a type of file that can be included in APEX.
type apexFileClass int
const (
app apexFileClass = iota
appSet
etc
javaSharedLib
nativeExecutable
nativeSharedLib
nativeTest
shBinary
)
var (
classes = map[string]apexFileClass{
"app": app,
"appSet": appSet,
"etc": etc,
"javaSharedLib": javaSharedLib,
"nativeExecutable": nativeExecutable,
"nativeSharedLib": nativeSharedLib,
"nativeTest": nativeTest,
"shBinary": shBinary,
}
)
// apexFile represents a file in an APEX bundle. This is created during the first half of
// GenerateAndroidBuildActions by traversing the dependencies of the APEX. Then in the second half
// of the function, this is used to create commands that copies the files into a staging directory,
// where they are packaged into the APEX file.
type apexFile struct {
// buildFile is put in the installDir inside the APEX.
builtFile android.Path
installDir string
partition string
customStem string
symlinks []string // additional symlinks
// Info for Android.mk Module name of `module` in AndroidMk. Note the generated AndroidMk
// module for apexFile is named something like <AndroidMk module name>.<apex name>[<apex
// suffix>]
androidMkModuleName string // becomes LOCAL_MODULE
class apexFileClass // becomes LOCAL_MODULE_CLASS
moduleDir string // becomes LOCAL_PATH
requiredModuleNames []string // becomes LOCAL_REQUIRED_MODULES
targetRequiredModuleNames []string // becomes LOCAL_TARGET_REQUIRED_MODULES
hostRequiredModuleNames []string // becomes LOCAL_HOST_REQUIRED_MODULES
dataPaths []android.DataPath // becomes LOCAL_TEST_DATA
jacocoReportClassesFile android.Path // only for javalibs and apps
lintDepSets java.LintDepSets // only for javalibs and apps
certificate java.Certificate // only for apps
overriddenPackageName string // only for apps
transitiveDep bool
isJniLib bool
multilib string
// TODO(jiyong): remove this
module android.Module
}
// TODO(jiyong): shorten the arglist using an option struct
func newApexFile(ctx android.BaseModuleContext, builtFile android.Path, androidMkModuleName string, installDir string, class apexFileClass, module android.Module) apexFile {
ret := apexFile{
builtFile: builtFile,
installDir: installDir,
androidMkModuleName: androidMkModuleName,
class: class,
module: module,
}
if module != nil {
ret.moduleDir = ctx.OtherModuleDir(module)
ret.partition = module.PartitionTag(ctx.DeviceConfig())
ret.requiredModuleNames = module.RequiredModuleNames()
ret.targetRequiredModuleNames = module.TargetRequiredModuleNames()
ret.hostRequiredModuleNames = module.HostRequiredModuleNames()
ret.multilib = module.Target().Arch.ArchType.Multilib
apex_available tracks static dependencies This change fixes a bug that apex_available is not enforced for static dependencies. For example, a module with 'apex_available: ["//apex_available:platform"]' was able to be statically linked to any APEX. This was happening because the check was done on the modules that are actually installed to an APEX. Static dependencies of the modules were not counted as they are not installed to the APEX as files. Fixing this bug by doing the check by traversing the tree in the method checkApexAvailability. This change includes a few number of related changes: 1) DepIsInSameApex implementation for cc.Module was changed as well. Previuosly, it returned false only when the dependency is actually a stub variant of a lib. Now, it returns false when the dependency has one or more stub variants. To understand why, we need to recall that when there is a dependency to a lib having stubs, we actually create two dependencies: to the non-stub variant and to the stub variant during the DepsMutator phase. And later in the build action generation phase, we choose one of them depending on the context. Also recall that an APEX variant is created only when DepIsInSameApex returns true. Given these, with the previous implementatin of DepIsInSameApex, we did create apex variants of the non-stub variant of the dependency, while not creating the apex variant for the stub variant. This is not right; we needlessly created the apex variant. The extra apex variant has caused no harm so far, but since the apex_available check became more correct, it actually breaks the build. To fix the issue, we stop creating the APEX variant both for non-stub and stub variants. 2) platform variant is created regardless of the apex_available value. This is required for the case when a library X that provides stub is in an APEX A and is configured to be available only for A. In that case, libs in other APEX can't use the stub library since the stub library is mutated only for apex A. By creating the platform variant for the stub library, it can be used from outside as the default dependency variation is set to the platform variant when creating the APEX variations. 3) The ApexAvailableWhitelist is added with the dependencies that were revealed with this change. Exempt-From-Owner-Approval: cherry-pick from internal Bug: 147671264 Test: m Merged-In: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e (cherry picked from commit fa89944c79f19552e906b41fd03a4981903eee7e) Change-Id: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e
2020-01-30 18:49:53 +01:00
}
return ret
}
func (af *apexFile) ok() bool {
return af.builtFile != nil && af.builtFile.String() != ""
}
// apexRelativePath returns the relative path of the given path from the install directory of this
// apexFile.
// TODO(jiyong): rename this
func (af *apexFile) apexRelativePath(path string) string {
return filepath.Join(af.installDir, path)
}
// path returns path of this apex file relative to the APEX root
func (af *apexFile) path() string {
return af.apexRelativePath(af.stem())
}
// stem returns the base filename of this apex file
func (af *apexFile) stem() string {
if af.customStem != "" {
return af.customStem
}
return af.builtFile.Base()
}
// symlinkPaths returns paths of the symlinks (if any) relative to the APEX root
func (af *apexFile) symlinkPaths() []string {
var ret []string
for _, symlink := range af.symlinks {
ret = append(ret, af.apexRelativePath(symlink))
apex_available tracks static dependencies This change fixes a bug that apex_available is not enforced for static dependencies. For example, a module with 'apex_available: ["//apex_available:platform"]' was able to be statically linked to any APEX. This was happening because the check was done on the modules that are actually installed to an APEX. Static dependencies of the modules were not counted as they are not installed to the APEX as files. Fixing this bug by doing the check by traversing the tree in the method checkApexAvailability. This change includes a few number of related changes: 1) DepIsInSameApex implementation for cc.Module was changed as well. Previuosly, it returned false only when the dependency is actually a stub variant of a lib. Now, it returns false when the dependency has one or more stub variants. To understand why, we need to recall that when there is a dependency to a lib having stubs, we actually create two dependencies: to the non-stub variant and to the stub variant during the DepsMutator phase. And later in the build action generation phase, we choose one of them depending on the context. Also recall that an APEX variant is created only when DepIsInSameApex returns true. Given these, with the previous implementatin of DepIsInSameApex, we did create apex variants of the non-stub variant of the dependency, while not creating the apex variant for the stub variant. This is not right; we needlessly created the apex variant. The extra apex variant has caused no harm so far, but since the apex_available check became more correct, it actually breaks the build. To fix the issue, we stop creating the APEX variant both for non-stub and stub variants. 2) platform variant is created regardless of the apex_available value. This is required for the case when a library X that provides stub is in an APEX A and is configured to be available only for A. In that case, libs in other APEX can't use the stub library since the stub library is mutated only for apex A. By creating the platform variant for the stub library, it can be used from outside as the default dependency variation is set to the platform variant when creating the APEX variations. 3) The ApexAvailableWhitelist is added with the dependencies that were revealed with this change. Exempt-From-Owner-Approval: cherry-pick from internal Bug: 147671264 Test: m Merged-In: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e (cherry picked from commit fa89944c79f19552e906b41fd03a4981903eee7e) Change-Id: Iaedc05494085ff4e8af227a6392bdd0c338b8e6e
2020-01-30 18:49:53 +01:00
}
return ret
}
// availableToPlatform tests whether this apexFile is from a module that can be installed to the
// platform.
func (af *apexFile) availableToPlatform() bool {
if af.module == nil {
return false
}
if am, ok := af.module.(android.ApexModule); ok {
return am.AvailableFor(android.AvailableToPlatform)
}
return false
}
////////////////////////////////////////////////////////////////////////////////////////////////////
// Mutators
//
// Brief description about mutators for APEX. The following three mutators are the most important
// ones.
//
// 1) DepsMutator: from the properties like native_shared_libs, java_libs, etc., modules are added
// to the (direct) dependencies of this APEX bundle.
//
// 2) apexInfoMutator: this is a post-deps mutator, so runs after DepsMutator. Its goal is to
// collect modules that are direct and transitive dependencies of each APEX bundle. The collected
// modules are marked as being included in the APEX via BuildForApex().
//
// 3) apexMutator: this is a post-deps mutator that runs after apexInfoMutator. For each module that
// are marked by the apexInfoMutator, apex variations are created using CreateApexVariations().
type dependencyTag struct {
blueprint.BaseDependencyTag
name string
// Determines if the dependent will be part of the APEX payload. Can be false for the
// dependencies to the signing key module, etc.
payload bool
// True if the dependent can only be a source module, false if a prebuilt module is a suitable
// replacement. This is needed because some prebuilt modules do not provide all the information
// needed by the apex.
sourceOnly bool
// If not-nil and an APEX is a member of an SDK then dependencies of that APEX with this tag will
// also be added as exported members of that SDK.
memberType android.SdkMemberType
}
func (d *dependencyTag) SdkMemberType(_ android.Module) android.SdkMemberType {
return d.memberType
}
func (d *dependencyTag) ExportMember() bool {
return true
}
func (d *dependencyTag) String() string {
return fmt.Sprintf("apex.dependencyTag{%q}", d.name)
}
func (d *dependencyTag) ReplaceSourceWithPrebuilt() bool {
return !d.sourceOnly
}
var _ android.ReplaceSourceWithPrebuilt = &dependencyTag{}
var _ android.SdkMemberDependencyTag = &dependencyTag{}
var (
androidAppTag = &dependencyTag{name: "androidApp", payload: true}
bpfTag = &dependencyTag{name: "bpf", payload: true}
certificateTag = &dependencyTag{name: "certificate"}
dclaTag = &dependencyTag{name: "dcla"}
executableTag = &dependencyTag{name: "executable", payload: true}
fsTag = &dependencyTag{name: "filesystem", payload: true}
bcpfTag = &dependencyTag{name: "bootclasspathFragment", payload: true, sourceOnly: true, memberType: java.BootclasspathFragmentSdkMemberType}
sscpfTag = &dependencyTag{name: "systemserverclasspathFragment", payload: true, sourceOnly: true, memberType: java.SystemServerClasspathFragmentSdkMemberType}
compatConfigTag = &dependencyTag{name: "compatConfig", payload: true, sourceOnly: true, memberType: java.CompatConfigSdkMemberType}
javaLibTag = &dependencyTag{name: "javaLib", payload: true}
jniLibTag = &dependencyTag{name: "jniLib", payload: true}
keyTag = &dependencyTag{name: "key"}
prebuiltTag = &dependencyTag{name: "prebuilt", payload: true}
rroTag = &dependencyTag{name: "rro", payload: true}
sharedLibTag = &dependencyTag{name: "sharedLib", payload: true}
testForTag = &dependencyTag{name: "test for"}
testTag = &dependencyTag{name: "test", payload: true}
shBinaryTag = &dependencyTag{name: "shBinary", payload: true}
)
// TODO(jiyong): shorten this function signature
func addDependenciesForNativeModules(ctx android.BottomUpMutatorContext, nativeModules ApexNativeDependencies, target android.Target, imageVariation string) {
binVariations := target.Variations()
libVariations := append(target.Variations(), blueprint.Variation{Mutator: "link", Variation: "shared"})
rustLibVariations := append(target.Variations(), blueprint.Variation{Mutator: "rust_libraries", Variation: "dylib"})
// Append "image" variation
binVariations = append(binVariations, blueprint.Variation{Mutator: "image", Variation: imageVariation})
libVariations = append(libVariations, blueprint.Variation{Mutator: "image", Variation: imageVariation})
rustLibVariations = append(rustLibVariations, blueprint.Variation{Mutator: "image", Variation: imageVariation})
// Use *FarVariation* to be able to depend on modules having conflicting variations with
// this module. This is required since arch variant of an APEX bundle is 'common' but it is
// 'arm' or 'arm64' for native shared libs.
ctx.AddFarVariationDependencies(binVariations, executableTag,
android.RemoveListFromList(nativeModules.Binaries, nativeModules.Exclude_binaries)...)
ctx.AddFarVariationDependencies(binVariations, testTag,
android.RemoveListFromList(nativeModules.Tests, nativeModules.Exclude_tests)...)
ctx.AddFarVariationDependencies(libVariations, jniLibTag,
android.RemoveListFromList(nativeModules.Jni_libs, nativeModules.Exclude_jni_libs)...)
ctx.AddFarVariationDependencies(libVariations, sharedLibTag,
android.RemoveListFromList(nativeModules.Native_shared_libs, nativeModules.Exclude_native_shared_libs)...)
ctx.AddFarVariationDependencies(rustLibVariations, sharedLibTag,
android.RemoveListFromList(nativeModules.Rust_dyn_libs, nativeModules.Exclude_rust_dyn_libs)...)
ctx.AddFarVariationDependencies(target.Variations(), fsTag,
android.RemoveListFromList(nativeModules.Filesystems, nativeModules.Exclude_filesystems)...)
}
func (a *apexBundle) combineProperties(ctx android.BottomUpMutatorContext) {
proptools.AppendProperties(&a.properties.Multilib, &a.targetProperties.Target.Android.Multilib, nil)
}
// getImageVariationPair returns a pair for the image variation name as its
// prefix and suffix. The prefix indicates whether it's core/vendor/product and the
// suffix indicates the vndk version when it's vendor or product.
// getImageVariation can simply join the result of this function to get the
// image variation name.
func (a *apexBundle) getImageVariationPair(deviceConfig android.DeviceConfig) (string, string) {
if a.vndkApex {
return cc.VendorVariationPrefix, a.vndkVersion(deviceConfig)
}
var prefix string
var vndkVersion string
if deviceConfig.VndkVersion() != "" {
if a.SocSpecific() || a.DeviceSpecific() {
prefix = cc.VendorVariationPrefix
vndkVersion = deviceConfig.VndkVersion()
} else if a.ProductSpecific() {
prefix = cc.ProductVariationPrefix
vndkVersion = deviceConfig.PlatformVndkVersion()
}
}
if vndkVersion == "current" {
vndkVersion = deviceConfig.PlatformVndkVersion()
}
if vndkVersion != "" {
return prefix, vndkVersion
}
return android.CoreVariation, "" // The usual case
}
// getImageVariation returns the image variant name for this apexBundle. In most cases, it's simply
// android.CoreVariation, but gets complicated for the vendor APEXes and the VNDK APEX.
func (a *apexBundle) getImageVariation(ctx android.BottomUpMutatorContext) string {
prefix, vndkVersion := a.getImageVariationPair(ctx.DeviceConfig())
return prefix + vndkVersion
}
func (a *apexBundle) DepsMutator(ctx android.BottomUpMutatorContext) {
// apexBundle is a multi-arch targets module. Arch variant of apexBundle is set to 'common'.
// arch-specific targets are enabled by the compile_multilib setting of the apex bundle. For
// each target os/architectures, appropriate dependencies are selected by their
// target.<os>.multilib.<type> groups and are added as (direct) dependencies.
targets := ctx.MultiTargets()
imageVariation := a.getImageVariation(ctx)
a.combineProperties(ctx)
has32BitTarget := false
for _, target := range targets {
if target.Arch.ArchType.Multilib == "lib32" {
has32BitTarget = true
}
}
for i, target := range targets {
var deps ApexNativeDependencies
// Add native modules targeting both ABIs. When multilib.* is omitted for
// native_shared_libs/jni_libs/tests, it implies multilib.both
deps.Merge(a.properties.Multilib.Both)
deps.Merge(ApexNativeDependencies{
Native_shared_libs: a.properties.Native_shared_libs,
Tests: a.properties.Tests,
Jni_libs: a.properties.Jni_libs,
Binaries: nil,
})
// Add native modules targeting the first ABI When multilib.* is omitted for
// binaries, it implies multilib.first
isPrimaryAbi := i == 0
if isPrimaryAbi {
deps.Merge(a.properties.Multilib.First)
deps.Merge(ApexNativeDependencies{
Native_shared_libs: nil,
Tests: nil,
Jni_libs: nil,
Binaries: a.properties.Binaries,
})
}
// Add native modules targeting either 32-bit or 64-bit ABI
switch target.Arch.ArchType.Multilib {
case "lib32":
deps.Merge(a.properties.Multilib.Lib32)
deps.Merge(a.properties.Multilib.Prefer32)
case "lib64":
deps.Merge(a.properties.Multilib.Lib64)
if !has32BitTarget {
deps.Merge(a.properties.Multilib.Prefer32)
}
}
// Add native modules targeting a specific arch variant
switch target.Arch.ArchType {
case android.Arm:
deps.Merge(a.archProperties.Arch.Arm.ApexNativeDependencies)
case android.Arm64:
deps.Merge(a.archProperties.Arch.Arm64.ApexNativeDependencies)
case android.Riscv64:
deps.Merge(a.archProperties.Arch.Riscv64.ApexNativeDependencies)
case android.X86:
deps.Merge(a.archProperties.Arch.X86.ApexNativeDependencies)
case android.X86_64:
deps.Merge(a.archProperties.Arch.X86_64.ApexNativeDependencies)
default:
panic(fmt.Errorf("unsupported arch %v\n", ctx.Arch().ArchType))
}
addDependenciesForNativeModules(ctx, deps, target, imageVariation)
ctx.AddFarVariationDependencies([]blueprint.Variation{
{Mutator: "os", Variation: target.OsVariation()},
{Mutator: "arch", Variation: target.ArchVariation()},
}, shBinaryTag, a.properties.Sh_binaries...)
}
// Common-arch dependencies come next
commonVariation := ctx.Config().AndroidCommonTarget.Variations()
ctx.AddFarVariationDependencies(commonVariation, rroTag, a.properties.Rros...)
ctx.AddFarVariationDependencies(commonVariation, bcpfTag, a.properties.Bootclasspath_fragments...)
ctx.AddFarVariationDependencies(commonVariation, sscpfTag, a.properties.Systemserverclasspath_fragments...)
ctx.AddFarVariationDependencies(commonVariation, javaLibTag, a.properties.Java_libs...)
ctx.AddFarVariationDependencies(commonVariation, fsTag, a.properties.Filesystems...)
ctx.AddFarVariationDependencies(commonVariation, compatConfigTag, a.properties.Compat_configs...)
}
// DepsMutator for the overridden properties.
func (a *apexBundle) OverridablePropertiesDepsMutator(ctx android.BottomUpMutatorContext) {
if a.overridableProperties.Allowed_files != nil {
android.ExtractSourceDeps(ctx, a.overridableProperties.Allowed_files)
}
commonVariation := ctx.Config().AndroidCommonTarget.Variations()
ctx.AddFarVariationDependencies(commonVariation, androidAppTag, a.overridableProperties.Apps...)
ctx.AddFarVariationDependencies(commonVariation, bpfTag, a.overridableProperties.Bpfs...)
if prebuilts := a.overridableProperties.Prebuilts; len(prebuilts) > 0 {
// For prebuilt_etc, use the first variant (64 on 64/32bit device, 32 on 32bit device)
// regardless of the TARGET_PREFER_* setting. See b/144532908
arches := ctx.DeviceConfig().Arches()
if len(arches) != 0 {
archForPrebuiltEtc := arches[0]
for _, arch := range arches {
// Prefer 64-bit arch if there is any
if arch.ArchType.Multilib == "lib64" {
archForPrebuiltEtc = arch
break
}
}
ctx.AddFarVariationDependencies([]blueprint.Variation{
{Mutator: "os", Variation: ctx.Os().String()},
{Mutator: "arch", Variation: archForPrebuiltEtc.String()},
}, prebuiltTag, prebuilts...)
}
}
// Dependencies for signing
if String(a.overridableProperties.Key) == "" {
ctx.PropertyErrorf("key", "missing")
return
}
ctx.AddDependency(ctx.Module(), keyTag, String(a.overridableProperties.Key))
cert := android.SrcIsModule(a.getCertString(ctx))
if cert != "" {
ctx.AddDependency(ctx.Module(), certificateTag, cert)
// empty cert is not an error. Cert and private keys will be directly found under
// PRODUCT_DEFAULT_DEV_CERTIFICATE
}
}
func apexDCLADepsMutator(mctx android.BottomUpMutatorContext) {
if !mctx.Config().ApexTrimEnabled() {
return
}
if a, ok := mctx.Module().(*apexBundle); ok && a.overridableProperties.Trim_against != nil {
commonVariation := mctx.Config().AndroidCommonTarget.Variations()
mctx.AddFarVariationDependencies(commonVariation, dclaTag, String(a.overridableProperties.Trim_against))
} else if o, ok := mctx.Module().(*OverrideApex); ok {
for _, p := range o.GetProperties() {
properties, ok := p.(*overridableProperties)
if !ok {
continue
}
if properties.Trim_against != nil {
commonVariation := mctx.Config().AndroidCommonTarget.Variations()
mctx.AddFarVariationDependencies(commonVariation, dclaTag, String(properties.Trim_against))
}
}
}
}
type DCLAInfo struct {
ProvidedLibs []string
}
var DCLAInfoProvider = blueprint.NewMutatorProvider[DCLAInfo]("apex_info")
type ApexBundleInfo struct {
Contents *android.ApexContents
}
var ApexBundleInfoProvider = blueprint.NewMutatorProvider[ApexBundleInfo]("apex_info")
var _ ApexInfoMutator = (*apexBundle)(nil)
func (a *apexBundle) ApexVariationName() string {
return a.properties.ApexVariationName
}
// ApexInfoMutator is responsible for collecting modules that need to have apex variants. They are
// identified by doing a graph walk starting from an apexBundle. Basically, all the (direct and
// indirect) dependencies are collected. But a few types of modules that shouldn't be included in
// the apexBundle (e.g. stub libraries) are not collected. Note that a single module can be depended
// on by multiple apexBundles. In that case, the module is collected for all of the apexBundles.
//
// For each dependency between an apex and an ApexModule an ApexInfo object describing the apex
// is passed to that module's BuildForApex(ApexInfo) method which collates them all in a list.
// The apexMutator uses that list to create module variants for the apexes to which it belongs.
// The relationship between module variants and apexes is not one-to-one as variants will be
// shared between compatible apexes.
func (a *apexBundle) ApexInfoMutator(mctx android.TopDownMutatorContext) {
// The VNDK APEX is special. For the APEX, the membership is described in a very different
// way. There is no dependency from the VNDK APEX to the VNDK libraries. Instead, VNDK
// libraries are self-identified by their vndk.enabled properties. There is no need to run
// this mutator for the APEX as nothing will be collected. So, let's return fast.
if a.vndkApex {
return
}
// Special casing for APEXes on non-system (e.g., vendor, odm, etc.) partitions. They are
// provided with a property named use_vndk_as_stable, which when set to true doesn't collect
// VNDK libraries as transitive dependencies. This option is useful for reducing the size of
// the non-system APEXes because the VNDK libraries won't be included (and duped) in the
// APEX, but shared across APEXes via the VNDK APEX.
useVndk := a.SocSpecific() || a.DeviceSpecific() || (a.ProductSpecific() && mctx.Config().EnforceProductPartitionInterface())
excludeVndkLibs := useVndk && a.useVndkAsStable(mctx)
if proptools.Bool(a.properties.Use_vndk_as_stable) {
if !useVndk {
mctx.PropertyErrorf("use_vndk_as_stable", "not supported for system/system_ext APEXes")
}
if a.minSdkVersionValue(mctx) != "" {
mctx.PropertyErrorf("use_vndk_as_stable", "not supported when min_sdk_version is set")
}
mctx.VisitDirectDepsWithTag(sharedLibTag, func(dep android.Module) {
if c, ok := dep.(*cc.Module); ok && c.IsVndk() {
mctx.PropertyErrorf("use_vndk_as_stable", "Trying to include a VNDK library(%s) while use_vndk_as_stable is true.", dep.Name())
}
})
if mctx.Failed() {
return
}
}
continueApexDepsWalk := func(child, parent android.Module) bool {
am, ok := child.(android.ApexModule)
if !ok || !am.CanHaveApexVariants() {
return false
}
Prevent ApexInfoMutator from creating unnecessary variants Adds the AlwaysRequireApexVariantTag interface to enable ApexInfoMutator to differentiate between a tag that is excluded from apex contents but still requires an apex variant and a tag that is excluded from apex contents and does not require an apex variant. That is needed to support the sdkMemberVersionedDepTag which excludes the target from being added to the APEX but requires an APEX variant. A more detailed explanation is in the comments. The AlwaysRequireApexVariant() method follows the pattern used in ReplaceSourceWithPrebuilt of having a method that returns a bool to trigger the behavior and not say ExcludeFromApexContentsTag that simply relies on the tag implementing an interface to trigger. That is because the former is more flexible and allows a tag type to parameterize the behavior if necessary. The tags that this will exclude from creating an apex variant are: * PrebuiltDepTag - by the time the apex variant has been created any preferred prebuilts will have replaced the sources so there is no need to create an APEX variant if the only dependency path from the APEX to the prebuilt is via this tag. * hiddenApiAnnotationsDependencyTag - the target of which is a purely build time artifect and MUST NEVER end up in the APEX. It will also stop calling DepIsInSameApex for any dependency created by the sdkMemberVersionedDepTag. Which will fix the issue reported in the bug. Bug: 182992071 Test: m nothing Change-Id: I9569e488d6446ca45d3ea8f32a9b74524eb865df
2021-03-17 14:25:29 +01:00
depTag := mctx.OtherModuleDependencyTag(child)
// Check to see if the tag always requires that the child module has an apex variant for every
// apex variant of the parent module. If it does not then it is still possible for something
// else, e.g. the DepIsInSameApex(...) method to decide that a variant is required.
if required, ok := depTag.(android.AlwaysRequireApexVariantTag); ok && required.AlwaysRequireApexVariant() {
return true
}
if !android.IsDepInSameApex(mctx, parent, child) {
return false
}
if excludeVndkLibs {
if c, ok := child.(*cc.Module); ok && c.IsVndk() {
return false
}
}
//TODO: b/296491928 Vendor APEX should use libbinder.ndk instead of libbinder once VNDK is fully deprecated.
if useVndk && mctx.Config().IsVndkDeprecated() && child.Name() == "libbinder" {
log.Print("Libbinder is linked from Vendor APEX ", a.Name(), " with module ", parent.Name())
return false
}
// By default, all the transitive dependencies are collected, unless filtered out
// above.
return true
}
// Records whether a certain module is included in this apexBundle via direct dependency or
// inndirect dependency.
contents := make(map[string]android.ApexMembership)
mctx.WalkDeps(func(child, parent android.Module) bool {
if !continueApexDepsWalk(child, parent) {
return false
}
// If the parent is apexBundle, this child is directly depended.
_, directDep := parent.(*apexBundle)
depName := mctx.OtherModuleName(child)
contents[depName] = contents[depName].Add(directDep)
return true
})
// The membership information is saved for later access
apexContents := android.NewApexContents(contents)
android.SetProvider(mctx, ApexBundleInfoProvider, ApexBundleInfo{
Contents: apexContents,
})
minSdkVersion := a.minSdkVersion(mctx)
// When min_sdk_version is not set, the apex is built against FutureApiLevel.
if minSdkVersion.IsNone() {
minSdkVersion = android.FutureApiLevel
}
// This is the main part of this mutator. Mark the collected dependencies that they need to
// be built for this apexBundle.
2021-05-12 10:13:56 +02:00
apexVariationName := mctx.ModuleName() // could be com.android.foo
a.properties.ApexVariationName = apexVariationName
testApexes := []string{}
if a.testApex {
testApexes = []string{apexVariationName}
}
apexInfo := android.ApexInfo{
ApexVariationName: apexVariationName,
MinSdkVersion: minSdkVersion,
Updatable: a.Updatable(),
UsePlatformApis: a.UsePlatformApis(),
InApexVariants: []string{apexVariationName},
InApexModules: []string{a.Name()}, // could be com.mycompany.android.foo
ApexContents: []*android.ApexContents{apexContents},
TestApexes: testApexes,
}
mctx.WalkDeps(func(child, parent android.Module) bool {
if !continueApexDepsWalk(child, parent) {
return false
}
child.(android.ApexModule).BuildForApex(apexInfo) // leave a mark!
return true
})
if a.dynamic_common_lib_apex() {
android.SetProvider(mctx, DCLAInfoProvider, DCLAInfo{
ProvidedLibs: a.properties.Native_shared_libs,
})
}
}
type ApexInfoMutator interface {
// ApexVariationName returns the name of the APEX variation to use in the apex
// mutator etc. It is the same name as ApexInfo.ApexVariationName.
ApexVariationName() string
// ApexInfoMutator implementations must call BuildForApex(ApexInfo) on any modules that are
// depended upon by an apex and which require an apex specific variant.
ApexInfoMutator(android.TopDownMutatorContext)
}
// apexInfoMutator delegates the work of identifying which modules need an ApexInfo and apex
// specific variant to modules that support the ApexInfoMutator.
// It also propagates updatable=true to apps of updatable apexes
func apexInfoMutator(mctx android.TopDownMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if a, ok := mctx.Module().(ApexInfoMutator); ok {
a.ApexInfoMutator(mctx)
}
enforceAppUpdatability(mctx)
}
// apexStrictUpdatibilityLintMutator propagates strict_updatability_linting to transitive deps of a mainline module
// This check is enforced for updatable modules
func apexStrictUpdatibilityLintMutator(mctx android.TopDownMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if apex, ok := mctx.Module().(*apexBundle); ok && apex.checkStrictUpdatabilityLinting() {
mctx.WalkDeps(func(child, parent android.Module) bool {
// b/208656169 Do not propagate strict updatability linting to libcore/
// These libs are available on the classpath during compilation
// These libs are transitive deps of the sdk. See java/sdk.go:decodeSdkDep
// Only skip libraries defined in libcore root, not subdirectories
if mctx.OtherModuleDir(child) == "libcore" {
// Do not traverse transitive deps of libcore/ libs
return false
}
if android.InList(child.Name(), skipLintJavalibAllowlist) {
return false
}
if lintable, ok := child.(java.LintDepSetsIntf); ok {
lintable.SetStrictUpdatabilityLinting(true)
}
// visit transitive deps
return true
})
}
}
// enforceAppUpdatability propagates updatable=true to apps of updatable apexes
func enforceAppUpdatability(mctx android.TopDownMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if apex, ok := mctx.Module().(*apexBundle); ok && apex.Updatable() {
// checking direct deps is sufficient since apex->apk is a direct edge, even when inherited via apex_defaults
mctx.VisitDirectDeps(func(module android.Module) {
// ignore android_test_app
if app, ok := module.(*java.AndroidApp); ok {
app.SetUpdatable(true)
}
})
}
}
// TODO: b/215736885 Whittle the denylist
// Transitive deps of certain mainline modules baseline NewApi errors
// Skip these mainline modules for now
var (
skipStrictUpdatabilityLintAllowlist = []string{
"com.android.art",
"com.android.art.debug",
"com.android.conscrypt",
"com.android.media",
// test apexes
"test_com.android.art",
"test_com.android.conscrypt",
"test_com.android.media",
"test_jitzygote_com.android.art",
}
// TODO: b/215736885 Remove this list
skipLintJavalibAllowlist = []string{
"conscrypt.module.platform.api.stubs",
"conscrypt.module.public.api.stubs",
"conscrypt.module.public.api.stubs.system",
"conscrypt.module.public.api.stubs.module_lib",
"framework-media.stubs",
"framework-media.stubs.system",
"framework-media.stubs.module_lib",
}
)
func (a *apexBundle) checkStrictUpdatabilityLinting() bool {
return a.Updatable() && !android.InList(a.ApexVariationName(), skipStrictUpdatabilityLintAllowlist)
}
// apexUniqueVariationsMutator checks if any dependencies use unique apex variations. If so, use
// unique apex variations for this module. See android/apex.go for more about unique apex variant.
// TODO(jiyong): move this to android/apex.go?
Reland: Deduplicate APEX variants that would build identically APEX variants that share the same SDK version and updatability almost always use identical command line arguments to build but with different intermediates directories. This causes unnecessary build time and disk space for duplicated work. Deduplicate APEX variants that would build identically. Create aliases from the per-APEX variations to the new shared variations so that the APEX modules can continue to depend on them via the APEX name as the variation. This has one significant change in behavior. Before this change, if an APEX had two libraries in its direct dependencies and one of those libraries depended on the other, and the second library had stubs, then the first library would depend on the implementation of the second library and not the stubs. After this change, if the first library is also present in a second APEX but the second library is not, then the common variant shared between the two APEXes would use the stubs, not the implementation. In a correctly configured set of build rules this change will be irrelevant, because if the compilation worked for the second APEX using stubs then it will work for the common variant using stubs. However, if an incorrect change to the build rules is made this could lead to confusing errors, as a previously-working common variant could suddenly stop building when a module is added to a new APEX without its dependencies that require implementation APIs to compile. This change reduces the number of modules in an AOSP arm64-userdebug build by 3% (52242 to 50586), reduces the number of variants of the libcutils module from 74 to 53, and reduces the number of variants of the massive libart[d] modules from 44 to 32. This relands I0529837476a253c32b3dfb98dcccf107427c742c with a fix to always mark permissions XML files of java_sdk_library modules as unique per apex since they contain the APEX filename, and a fix to UpdateUniqueApexVariationsForDeps to check ApexInfo.InApexes instead of DepIsInSameApex to check if two modules are in the same apex to account for a module that depends on another in a way that doesn't normally include the dependency in the APEX (e.g. a libs property), but the dependency is directly included in the APEX. Bug: 164216768 Test: go test ./build/soong/apex/... Change-Id: I2ae170601f764e5b88d0be2e0e6adc84e3a4d9cc
2020-08-11 21:17:01 +02:00
func apexUniqueVariationsMutator(mctx android.BottomUpMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if am, ok := mctx.Module().(android.ApexModule); ok {
android.UpdateUniqueApexVariationsForDeps(mctx, am)
}
}
// apexTestForDepsMutator checks if this module is a test for an apex. If so, add a dependency on
// the apex in order to retrieve its contents later.
// TODO(jiyong): move this to android/apex.go?
func apexTestForDepsMutator(mctx android.BottomUpMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if am, ok := mctx.Module().(android.ApexModule); ok {
if testFor := am.TestFor(); len(testFor) > 0 {
mctx.AddFarVariationDependencies([]blueprint.Variation{
{Mutator: "os", Variation: am.Target().OsVariation()},
{"arch", "common"},
}, testForTag, testFor...)
}
}
}
// TODO(jiyong): move this to android/apex.go?
func apexTestForMutator(mctx android.BottomUpMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if _, ok := mctx.Module().(android.ApexModule); ok {
var contents []*android.ApexContents
for _, testFor := range mctx.GetDirectDepsWithTag(testForTag) {
abInfo, _ := android.OtherModuleProvider(mctx, testFor, ApexBundleInfoProvider)
contents = append(contents, abInfo.Contents)
}
android.SetProvider(mctx, android.ApexTestForInfoProvider, android.ApexTestForInfo{
ApexContents: contents,
})
Reland: Deduplicate APEX variants that would build identically APEX variants that share the same SDK version and updatability almost always use identical command line arguments to build but with different intermediates directories. This causes unnecessary build time and disk space for duplicated work. Deduplicate APEX variants that would build identically. Create aliases from the per-APEX variations to the new shared variations so that the APEX modules can continue to depend on them via the APEX name as the variation. This has one significant change in behavior. Before this change, if an APEX had two libraries in its direct dependencies and one of those libraries depended on the other, and the second library had stubs, then the first library would depend on the implementation of the second library and not the stubs. After this change, if the first library is also present in a second APEX but the second library is not, then the common variant shared between the two APEXes would use the stubs, not the implementation. In a correctly configured set of build rules this change will be irrelevant, because if the compilation worked for the second APEX using stubs then it will work for the common variant using stubs. However, if an incorrect change to the build rules is made this could lead to confusing errors, as a previously-working common variant could suddenly stop building when a module is added to a new APEX without its dependencies that require implementation APIs to compile. This change reduces the number of modules in an AOSP arm64-userdebug build by 3% (52242 to 50586), reduces the number of variants of the libcutils module from 74 to 53, and reduces the number of variants of the massive libart[d] modules from 44 to 32. This relands I0529837476a253c32b3dfb98dcccf107427c742c with a fix to always mark permissions XML files of java_sdk_library modules as unique per apex since they contain the APEX filename, and a fix to UpdateUniqueApexVariationsForDeps to check ApexInfo.InApexes instead of DepIsInSameApex to check if two modules are in the same apex to account for a module that depends on another in a way that doesn't normally include the dependency in the APEX (e.g. a libs property), but the dependency is directly included in the APEX. Bug: 164216768 Test: go test ./build/soong/apex/... Change-Id: I2ae170601f764e5b88d0be2e0e6adc84e3a4d9cc
2020-08-11 21:17:01 +02:00
}
}
// markPlatformAvailability marks whether or not a module can be available to platform. A module
// cannot be available to platform if 1) it is explicitly marked as not available (i.e.
// "//apex_available:platform" is absent) or 2) it depends on another module that isn't (or can't
// be) available to platform
// TODO(jiyong): move this to android/apex.go?
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
func markPlatformAvailability(mctx android.BottomUpMutatorContext) {
// Recovery is not considered as platform
if mctx.Module().InstallInRecovery() {
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
return
}
am, ok := mctx.Module().(android.ApexModule)
if !ok {
return
}
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
availableToPlatform := am.AvailableFor(android.AvailableToPlatform)
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
// If any of the dep is not available to platform, this module is also considered as being
// not available to platform even if it has "//apex_available:platform"
mctx.VisitDirectDeps(func(child android.Module) {
if !android.IsDepInSameApex(mctx, am, child) {
// if the dependency crosses apex boundary, don't consider it
return
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
}
if dep, ok := child.(android.ApexModule); ok && dep.NotAvailableForPlatform() {
availableToPlatform = false
// TODO(b/154889534) trigger an error when 'am' has
// "//apex_available:platform"
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
}
})
// Exception 1: check to see if the module always requires it.
if am.AlwaysRequiresPlatformApexVariant() {
availableToPlatform = true
mark platform un-availability A module is marked unavailable for platform when 1) it does not have "//apex_available:platform" in its apex_available property, or 2) it depends on another module that is unavailable for platform. In that case, LOCAL_NOT_AVAILABLE_FOR_PLATFORM is set to true for the module in the Make world. Later, that flag is used to ensure that there is no module with the flag is installed to the device. The reason why this isn't entirely done in Soong is because Soong doesn't know if a module will be installed to the device or not. To explain this, let's have an example. cc_test { name: "mytest", static_libs: ["libfoo"]} cc_library_static { name: "libfoo", static_libs: ["libbar"]} cc_library { name: "libbar", apex_available: ["com.android.xxx"]} Here, libbar is not available for platform, but is used by libfoo which is available for platform (apex_available defaults to "//apex_available:platform"). libfoo is again depended on by mytest which again is available for platform. The use of libbar should be allowed in the context of test; we don't want to make libbar available to platform just for the dependency from test because it will allow non-test uses of the library as well. Soong by itself can't tell whether libfoo and libbar are used only in the context of a test. There could be another module depending them, e.g., cc_library_shared { name: "mylib", static_libs: ["libfoo"] } can exist and it might be installed to the device, in which case we really should trigger an error. Since Make has the knowledge of what's installed and what's not, the check should be done there. Bug: 153073816 Test: m Test: remove "//apex_available:platform" from libmdnssd (it is currently installed to /system/lib), and check that `m system_image` fails Change-Id: Ia304cc5f41f173229e8a154e90cea4dce46dcebe
2020-04-07 09:37:39 +02:00
}
// Exception 2: bootstrap bionic libraries are also always available to platform
if cc.InstallToBootstrap(mctx.ModuleName(), mctx.Config()) {
availableToPlatform = true
}
if !availableToPlatform {
am.SetNotAvailableForPlatform()
}
}
// apexMutator visits each module and creates apex variations if the module was marked in the
// previous run of apexInfoMutator.
func apexMutator(mctx android.BottomUpMutatorContext) {
if !mctx.Module().Enabled() {
return
}
// This is the usual path.
if am, ok := mctx.Module().(android.ApexModule); ok && am.CanHaveApexVariants() {
android.CreateApexVariations(mctx, am)
return
}
// apexBundle itself is mutated so that it and its dependencies have the same apex variant.
if ai, ok := mctx.Module().(ApexInfoMutator); ok && apexModuleTypeRequiresVariant(ai) {
apexBundleName := ai.ApexVariationName()
mctx.CreateVariations(apexBundleName)
if strings.HasPrefix(apexBundleName, "com.android.art") {
// Create an alias from the platform variant. This is done to make
// test_for dependencies work for modules that are split by the APEX
// mutator, since test_for dependencies always go to the platform variant.
// This doesn't happen for normal APEXes that are disjunct, so only do
// this for the overlapping ART APEXes.
// TODO(b/183882457): Remove this if the test_for functionality is
// refactored to depend on the proper APEX variants instead of platform.
mctx.CreateAliasVariation("", apexBundleName)
}
} else if o, ok := mctx.Module().(*OverrideApex); ok {
apexBundleName := o.GetOverriddenModuleName()
if apexBundleName == "" {
mctx.ModuleErrorf("base property is not set")
return
}
mctx.CreateVariations(apexBundleName)
if strings.HasPrefix(apexBundleName, "com.android.art") {
// TODO(b/183882457): See note for CreateAliasVariation above.
mctx.CreateAliasVariation("", apexBundleName)
}
}
}
// apexModuleTypeRequiresVariant determines whether the module supplied requires an apex specific
// variant.
func apexModuleTypeRequiresVariant(module ApexInfoMutator) bool {
if a, ok := module.(*apexBundle); ok {
// TODO(jiyong): document the reason why the VNDK APEX is an exception here.
return !a.vndkApex
}
return true
}
// See android.UpdateDirectlyInAnyApex
// TODO(jiyong): move this to android/apex.go?
func apexDirectlyInAnyMutator(mctx android.BottomUpMutatorContext) {
if !mctx.Module().Enabled() {
return
}
if am, ok := mctx.Module().(android.ApexModule); ok {
android.UpdateDirectlyInAnyApex(mctx, am)
}
}
const (
// File extensions of an APEX for different packaging methods
imageApexSuffix = ".apex"
imageCapexSuffix = ".capex"
// variant names each of which is for a packaging method
imageApexType = "image"
ext4FsType = "ext4"
f2fsFsType = "f2fs"
erofsFsType = "erofs"
)
var _ android.DepIsInSameApex = (*apexBundle)(nil)
// Implements android.DepInInSameApex
func (a *apexBundle) DepIsInSameApex(_ android.BaseModuleContext, _ android.Module) bool {
// direct deps of an APEX bundle are all part of the APEX bundle
// TODO(jiyong): shouldn't we look into the payload field of the dependencyTag?
return true
}
var _ android.OutputFileProducer = (*apexBundle)(nil)
// Implements android.OutputFileProducer
func (a *apexBundle) OutputFiles(tag string) (android.Paths, error) {
switch tag {
Differentiate between no dist tag and an empty dist tag Change https://r.android.com/1335521 added tag property to the Dist struct so that it could be used to select one of a number of different output files to copy to the dist instead of the single file that the module type made available for dist. The output files were selected by passing the tag to OutputFiles(tag). Module types that wanted to support this new approach had to explicitly set AndroidMkEntries.DistFiles = GenerateTaggedDistFiles(module). Unfortunately, doing that had a side effect of changing the behavior of dist entries without a tag. That was because the change treated a tag that was not specified, as being the same as "". So, prior to the change no tag meant use the default dist file but after it meant use the paths returned by OutputFiles(""). That changed the behavior of the java.Library type which affected the behavior of the android_app module type. Prior to the change the java_library would make the Library.outputFile available for dist when no tag was specified. After that change it would make Library.outputFile plus Library.extraOutputFiles. The latter is usually empty except for android_app which adds some extra files into there which will now be copied to the dist. That change may have been intentional but there was no mention of it in the change or the bug. Even if it wasn't intentional it may still be beneficial. Any module type that wants to add support for tags in dist runs the risk of introducing similar changes in behavior. This change differentiates between the tag not being set and the tag being set to "" to avoid that possibility and to make the default behavior explicit for those module types that have switched. It does so as follows: * Adds a DefaultDistTag constant that is used when the tag is not set. It is a string that is unlikely to be used as an actual tag as it does not start with a . and uses some special characters. * The DefaultDistTag is used in MakeDefaultDistFiles(paths) to indicate that the supplied paths are the default ones and and also in GenerateTaggedDistFiles() for Dist structures that have no tag property set. * The DefaultDistTag is passed to OutputFiles(tag) just in case the module type has explicitly defined the paths to associate with that tag in there. If it has then it overrides the legacy behavior. If it has not then it is just ignored and falls back to using the previous behavior. * The java.Library.OutputFiles(tag) method explicitly handles the DefaultDistTag and returns Library.outputFile for it which restores the behavior from before the change that added dist.tag support. * Similar change was made to apexBundle.OutputFiles(tag) in order to preserve its previous behaviour. * The customModule used by TestGetDistContributions has been modified to also preserve its previous behavior after this change. Test: m nothing m dist sdk - before and after this change, compare result to make sure that there are no significant differences. Test the effect on the apex by following instructions in http://b/172951145 Bug: 174226317 Change-Id: Ib8f0d9307751cc2ed34e3d9a5538d3c144666f6d
2020-11-25 17:37:46 +01:00
case "", android.DefaultDistTag:
// This is the default dist path.
return android.Paths{a.outputFile}, nil
case imageApexSuffix:
// uncompressed one
if a.outputApexFile != nil {
return android.Paths{a.outputApexFile}, nil
}
fallthrough
default:
return nil, fmt.Errorf("unsupported module reference tag %q", tag)
}
}
var _ multitree.Exportable = (*apexBundle)(nil)
func (a *apexBundle) Exportable() bool {
return true
}
func (a *apexBundle) TaggedOutputs() map[string]android.Paths {
ret := make(map[string]android.Paths)
ret["apex"] = android.Paths{a.outputFile}
return ret
}
var _ cc.Coverage = (*apexBundle)(nil)
// Implements cc.Coverage
func (a *apexBundle) IsNativeCoverageNeeded(ctx android.BaseModuleContext) bool {
return ctx.DeviceConfig().NativeCoverageEnabled()
}
// Implements cc.Coverage
func (a *apexBundle) SetPreventInstall() {
a.properties.PreventInstall = true
}
// Implements cc.Coverage
func (a *apexBundle) HideFromMake() {
a.properties.HideFromMake = true
// This HideFromMake is shadowing the ModuleBase one, call through to it for now.
// TODO(ccross): untangle these
a.ModuleBase.HideFromMake()
}
// Implements cc.Coverage
func (a *apexBundle) MarkAsCoverageVariant(coverage bool) {
a.properties.IsCoverageVariant = coverage
}
// Implements cc.Coverage
func (a *apexBundle) EnableCoverageIfNeeded() {}
var _ android.ApexBundleDepsInfoIntf = (*apexBundle)(nil)
// Implements android.ApexBundleDepsInfoIntf
func (a *apexBundle) Updatable() bool {
return proptools.BoolDefault(a.properties.Updatable, true)
}
func (a *apexBundle) FutureUpdatable() bool {
return proptools.BoolDefault(a.properties.Future_updatable, false)
}
func (a *apexBundle) UsePlatformApis() bool {
return proptools.BoolDefault(a.properties.Platform_apis, false)
}
// getCertString returns the name of the cert that should be used to sign this APEX. This is
// basically from the "certificate" property, but could be overridden by the device config.
func (a *apexBundle) getCertString(ctx android.BaseModuleContext) string {
moduleName := ctx.ModuleName()
// VNDK APEXes share the same certificate. To avoid adding a new VNDK version to the
// OVERRIDE_* list, we check with the pseudo module name to see if its certificate is
// overridden.
if a.vndkApex {
moduleName = vndkApexName
}
certificate, overridden := ctx.DeviceConfig().OverrideCertificateFor(moduleName)
if overridden {
return ":" + certificate
}
return String(a.overridableProperties.Certificate)
}
// See the installable property
func (a *apexBundle) installable() bool {
return !a.properties.PreventInstall && (a.properties.Installable == nil || proptools.Bool(a.properties.Installable))
}
// See the generate_hashtree property
func (a *apexBundle) shouldGenerateHashtree() bool {
return proptools.BoolDefault(a.properties.Generate_hashtree, true)
}
// See the test_only_unsigned_payload property
func (a *apexBundle) testOnlyShouldSkipPayloadSign() bool {
return proptools.Bool(a.properties.Test_only_unsigned_payload)
}
// See the test_only_force_compression property
func (a *apexBundle) testOnlyShouldForceCompression() bool {
return proptools.Bool(a.properties.Test_only_force_compression)
}
// See the dynamic_common_lib_apex property
func (a *apexBundle) dynamic_common_lib_apex() bool {
return proptools.BoolDefault(a.properties.Dynamic_common_lib_apex, false)
}
// See the list of libs to trim
func (a *apexBundle) libs_to_trim(ctx android.ModuleContext) []string {
dclaModules := ctx.GetDirectDepsWithTag(dclaTag)
if len(dclaModules) > 1 {
panic(fmt.Errorf("expected exactly at most one dcla dependency, got %d", len(dclaModules)))
}
if len(dclaModules) > 0 {
DCLAInfo, _ := android.OtherModuleProvider(ctx, dclaModules[0], DCLAInfoProvider)
return DCLAInfo.ProvidedLibs
}
return []string{}
}
// These functions are interfacing with cc/sanitizer.go. The entire APEX (along with all of its
// members) can be sanitized, either forcibly, or by the global configuration. For some of the
// sanitizers, extra dependencies can be forcibly added as well.
func (a *apexBundle) EnableSanitizer(sanitizerName string) {
if !android.InList(sanitizerName, a.properties.SanitizerNames) {
a.properties.SanitizerNames = append(a.properties.SanitizerNames, sanitizerName)
}
}
func (a *apexBundle) IsSanitizerEnabled(config android.Config, sanitizerName string) bool {
if android.InList(sanitizerName, a.properties.SanitizerNames) {
return true
}
// Then follow the global setting
var globalSanitizerNames []string
arches := config.SanitizeDeviceArch()
if len(arches) == 0 || android.InList(a.Arch().ArchType.Name, arches) {
globalSanitizerNames = config.SanitizeDevice()
}
return android.InList(sanitizerName, globalSanitizerNames)
}
func (a *apexBundle) AddSanitizerDependencies(ctx android.BottomUpMutatorContext, sanitizerName string) {
// TODO(jiyong): move this info (the sanitizer name, the lib name, etc.) to cc/sanitize.go
// Keep only the mechanism here.
if sanitizerName == "hwaddress" && strings.HasPrefix(a.Name(), "com.android.runtime") {
imageVariation := a.getImageVariation(ctx)
for _, target := range ctx.MultiTargets() {
if target.Arch.ArchType.Multilib == "lib64" {
addDependenciesForNativeModules(ctx, ApexNativeDependencies{
Native_shared_libs: []string{"libclang_rt.hwasan"},
Tests: nil,
Jni_libs: nil,
Binaries: nil,
}, target, imageVariation)
break
}
}
}
}
// apexFileFor<Type> functions below create an apexFile struct for a given Soong module. The
// returned apexFile saves information about the Soong module that will be used for creating the
// build rules.
func apexFileForNativeLibrary(ctx android.BaseModuleContext, ccMod *cc.Module, handleSpecialLibs bool) apexFile {
// Decide the APEX-local directory by the multilib of the library In the future, we may
// query this to the module.
// TODO(jiyong): use the new PackagingSpec
var dirInApex string
switch ccMod.Arch().ArchType.Multilib {
case "lib32":
dirInApex = "lib"
case "lib64":
dirInApex = "lib64"
}
if ccMod.Target().NativeBridge == android.NativeBridgeEnabled {
dirInApex = filepath.Join(dirInApex, ccMod.Target().NativeBridgeRelativePath)
}
if handleSpecialLibs && cc.InstallToBootstrap(ccMod.BaseModuleName(), ctx.Config()) {
// Special case for Bionic libs and other libs installed with them. This is to
// prevent those libs from being included in the search path
// /apex/com.android.runtime/${LIB}. This exclusion is required because those libs
// in the Runtime APEX are available via the legacy paths in /system/lib/. By the
// init process, the libs in the APEX are bind-mounted to the legacy paths and thus
// will be loaded into the default linker namespace (aka "platform" namespace). If
// the libs are directly in /apex/com.android.runtime/${LIB} then the same libs will
// be loaded again into the runtime linker namespace, which will result in double
// loading of them, which isn't supported.
dirInApex = filepath.Join(dirInApex, "bionic")
}
// This needs to go after the runtime APEX handling because otherwise we would get
// weird paths like lib64/rel_install_path/bionic rather than
// lib64/bionic/rel_install_path.
dirInApex = filepath.Join(dirInApex, ccMod.RelativeInstallPath())
fileToCopy := android.OutputFileForModule(ctx, ccMod, "")
androidMkModuleName := ccMod.BaseModuleName() + ccMod.Properties.SubName
return newApexFile(ctx, fileToCopy, androidMkModuleName, dirInApex, nativeSharedLib, ccMod)
}
func apexFileForExecutable(ctx android.BaseModuleContext, cc *cc.Module) apexFile {
dirInApex := "bin"
if cc.Target().NativeBridge == android.NativeBridgeEnabled {
dirInApex = filepath.Join(dirInApex, cc.Target().NativeBridgeRelativePath)
}
dirInApex = filepath.Join(dirInApex, cc.RelativeInstallPath())
fileToCopy := android.OutputFileForModule(ctx, cc, "")
androidMkModuleName := cc.BaseModuleName() + cc.Properties.SubName
af := newApexFile(ctx, fileToCopy, androidMkModuleName, dirInApex, nativeExecutable, cc)
af.symlinks = cc.Symlinks()
af.dataPaths = cc.DataPaths()
return af
}
func apexFileForRustExecutable(ctx android.BaseModuleContext, rustm *rust.Module) apexFile {
dirInApex := "bin"
if rustm.Target().NativeBridge == android.NativeBridgeEnabled {
dirInApex = filepath.Join(dirInApex, rustm.Target().NativeBridgeRelativePath)
}
dirInApex = filepath.Join(dirInApex, rustm.RelativeInstallPath())
fileToCopy := android.OutputFileForModule(ctx, rustm, "")
androidMkModuleName := rustm.BaseModuleName() + rustm.Properties.SubName
af := newApexFile(ctx, fileToCopy, androidMkModuleName, dirInApex, nativeExecutable, rustm)
return af
}
func apexFileForRustLibrary(ctx android.BaseModuleContext, rustm *rust.Module) apexFile {
// Decide the APEX-local directory by the multilib of the library
// In the future, we may query this to the module.
var dirInApex string
switch rustm.Arch().ArchType.Multilib {
case "lib32":
dirInApex = "lib"
case "lib64":
dirInApex = "lib64"
}
if rustm.Target().NativeBridge == android.NativeBridgeEnabled {
dirInApex = filepath.Join(dirInApex, rustm.Target().NativeBridgeRelativePath)
}
dirInApex = filepath.Join(dirInApex, rustm.RelativeInstallPath())
fileToCopy := android.OutputFileForModule(ctx, rustm, "")
androidMkModuleName := rustm.BaseModuleName() + rustm.Properties.SubName
return newApexFile(ctx, fileToCopy, androidMkModuleName, dirInApex, nativeSharedLib, rustm)
}
func apexFileForShBinary(ctx android.BaseModuleContext, sh *sh.ShBinary) apexFile {
dirInApex := filepath.Join("bin", sh.SubDir())
if sh.Target().NativeBridge == android.NativeBridgeEnabled {
dirInApex = filepath.Join(dirInApex, sh.Target().NativeBridgeRelativePath)
}
fileToCopy := sh.OutputFile()
af := newApexFile(ctx, fileToCopy, sh.BaseModuleName(), dirInApex, shBinary, sh)
af.symlinks = sh.Symlinks()
return af
}
func apexFileForPrebuiltEtc(ctx android.BaseModuleContext, prebuilt prebuilt_etc.PrebuiltEtcModule, depName string) apexFile {
dirInApex := filepath.Join(prebuilt.BaseDir(), prebuilt.SubDir())
fileToCopy := prebuilt.OutputFile()
return newApexFile(ctx, fileToCopy, depName, dirInApex, etc, prebuilt)
}
func apexFileForCompatConfig(ctx android.BaseModuleContext, config java.PlatformCompatConfigIntf, depName string) apexFile {
dirInApex := filepath.Join("etc", config.SubDir())
fileToCopy := config.CompatConfig()
return newApexFile(ctx, fileToCopy, depName, dirInApex, etc, config)
}
// javaModule is an interface to handle all Java modules (java_library, dex_import, etc) in the same
// way.
type javaModule interface {
android.Module
BaseModuleName() string
DexJarBuildPath() java.OptionalDexJarPath
JacocoReportClassesFile() android.Path
LintDepSets() java.LintDepSets
Stem() string
}
var _ javaModule = (*java.Library)(nil)
var _ javaModule = (*java.Import)(nil)
var _ javaModule = (*java.SdkLibrary)(nil)
var _ javaModule = (*java.DexImport)(nil)
var _ javaModule = (*java.SdkLibraryImport)(nil)
// apexFileForJavaModule creates an apexFile for a java module's dex implementation jar.
func apexFileForJavaModule(ctx android.BaseModuleContext, module javaModule) apexFile {
return apexFileForJavaModuleWithFile(ctx, module, module.DexJarBuildPath().PathOrNil())
}
// apexFileForJavaModuleWithFile creates an apexFile for a java module with the supplied file.
func apexFileForJavaModuleWithFile(ctx android.BaseModuleContext, module javaModule, dexImplementationJar android.Path) apexFile {
dirInApex := "javalib"
af := newApexFile(ctx, dexImplementationJar, module.BaseModuleName(), dirInApex, javaSharedLib, module)
af.jacocoReportClassesFile = module.JacocoReportClassesFile()
af.lintDepSets = module.LintDepSets()
af.customStem = module.Stem() + ".jar"
if dexpreopter, ok := module.(java.DexpreopterInterface); ok {
for _, install := range dexpreopter.DexpreoptBuiltInstalledForApex() {
af.requiredModuleNames = append(af.requiredModuleNames, install.FullModuleName())
}
}
return af
}
func apexFileForJavaModuleProfile(ctx android.BaseModuleContext, module javaModule) *apexFile {
if dexpreopter, ok := module.(java.DexpreopterInterface); ok {
if profilePathOnHost := dexpreopter.OutputProfilePathOnHost(); profilePathOnHost != nil {
dirInApex := "javalib"
af := newApexFile(ctx, profilePathOnHost, module.BaseModuleName()+"-profile", dirInApex, etc, nil)
af.customStem = module.Stem() + ".jar.prof"
return &af
}
}
return nil
}
// androidApp is an interface to handle all app modules (android_app, android_app_import, etc.) in
// the same way.
type androidApp interface {
android.Module
Privileged() bool
InstallApkName() string
OutputFile() android.Path
JacocoReportClassesFile() android.Path
Certificate() java.Certificate
BaseModuleName() string
LintDepSets() java.LintDepSets
PrivAppAllowlist() android.OptionalPath
}
var _ androidApp = (*java.AndroidApp)(nil)
var _ androidApp = (*java.AndroidAppImport)(nil)
func sanitizedBuildIdForPath(ctx android.BaseModuleContext) string {
buildId := ctx.Config().BuildId()
// The build ID is used as a suffix for a filename, so ensure that
// the set of characters being used are sanitized.
// - any word character: [a-zA-Z0-9_]
// - dots: .
// - dashes: -
validRegex := regexp.MustCompile(`^[\w\.\-\_]+$`)
if !validRegex.MatchString(buildId) {
ctx.ModuleErrorf("Unable to use build id %s as filename suffix, valid characters are [a-z A-Z 0-9 _ . -].", buildId)
}
return buildId
}
func apexFilesForAndroidApp(ctx android.BaseModuleContext, aapp androidApp) []apexFile {
appDir := "app"
if aapp.Privileged() {
appDir = "priv-app"
}
// TODO(b/224589412, b/226559955): Ensure that the subdirname is suffixed
// so that PackageManager correctly invalidates the existing installed apk
// in favour of the new APK-in-APEX. See bugs for more information.
dirInApex := filepath.Join(appDir, aapp.InstallApkName()+"@"+sanitizedBuildIdForPath(ctx))
fileToCopy := aapp.OutputFile()
af := newApexFile(ctx, fileToCopy, aapp.BaseModuleName(), dirInApex, app, aapp)
af.jacocoReportClassesFile = aapp.JacocoReportClassesFile()
af.lintDepSets = aapp.LintDepSets()
af.certificate = aapp.Certificate()
if app, ok := aapp.(interface {
OverriddenManifestPackageName() string
}); ok {
af.overriddenPackageName = app.OverriddenManifestPackageName()
}
apexFiles := []apexFile{}
if allowlist := aapp.PrivAppAllowlist(); allowlist.Valid() {
dirInApex := filepath.Join("etc", "permissions")
privAppAllowlist := newApexFile(ctx, allowlist.Path(), aapp.BaseModuleName()+"_privapp", dirInApex, etc, aapp)
apexFiles = append(apexFiles, privAppAllowlist)
}
apexFiles = append(apexFiles, af)
return apexFiles
}
func apexFileForRuntimeResourceOverlay(ctx android.BaseModuleContext, rro java.RuntimeResourceOverlayModule) apexFile {
rroDir := "overlay"
dirInApex := filepath.Join(rroDir, rro.Theme())
fileToCopy := rro.OutputFile()
af := newApexFile(ctx, fileToCopy, rro.Name(), dirInApex, app, rro)
af.certificate = rro.Certificate()
if a, ok := rro.(interface {
OverriddenManifestPackageName() string
}); ok {
af.overriddenPackageName = a.OverriddenManifestPackageName()
}
return af
}
func apexFileForBpfProgram(ctx android.BaseModuleContext, builtFile android.Path, apex_sub_dir string, bpfProgram bpf.BpfModule) apexFile {
dirInApex := filepath.Join("etc", "bpf", apex_sub_dir)
return newApexFile(ctx, builtFile, builtFile.Base(), dirInApex, etc, bpfProgram)
}
func apexFileForFilesystem(ctx android.BaseModuleContext, buildFile android.Path, fs filesystem.Filesystem) apexFile {
dirInApex := filepath.Join("etc", "fs")
return newApexFile(ctx, buildFile, buildFile.Base(), dirInApex, etc, fs)
}
Export dex implementation jars from prebuilt_apex Dexpreopt and boot jars package check all require access to dex implementation jars created for java_library and java_sdk_library. They were available when building from source but not when building from prebuilts, even though they are embedded within the .apex files that are referenced from prebuilt_apex. This changes adds support to prebuilt_apex to export the dex implementation jars and updates java_import to use those exported dex implementation jars. In a source build dexpreopt/boot jars package check access the apex (or platform) specific variant of a java_library, e.g. core-oj, from which it retrieves the dex implementation jar path. After this change in a prebuilt build dexpreopt/boot jars package check behave in the same way except in this case they retrieve the dex implementation jar path from the apex (or platform) specific variant of the java_import, e.g. core-oj. The work to export files from a `.apex` file for use by other modules is performed by a new `deapexer` module type. It is not used directly in an `Android.bp` file but instead is created implicitly by `prebuilt_apex`, In order to do that this contains the following changes: * Adds a new `dexapexer` module type to handle the exporting of files from the `.apex` file. * Adds an exported_java_libs property to prebuilt_apex to specify the set of libraries whose dex implementation jars need exporting. * Creates apex specific variants of the libraries listed in the exported_java_libs property. * Adds the set of exported files to the ApexInfo to make them available to the apex specific variants. * Prevents the prebuilt_apex variants from being merged together as they will not be compatible. * Modifies java_import to use the exported file for variants of a prebuilt_apex. * Adds a ninja rule to unpack (using deapexer) the contents of the prebuilt_apex's apex file, verify that the required files are present and make them available as outputs for other rules to use. * Some minor refactorings to support these changes. * Adds tests to cover prebuilt only, prebuilt with source preferred, and prebuilt preferred with source. Test: m nothing Bug: 171061220 Change-Id: Ic9bed81fb65b92f0d59f64c0bce168a9ed44cfac
2020-11-02 18:32:38 +01:00
// WalkPayloadDeps visits dependencies that contributes to the payload of this APEX. For each of the
// visited module, the `do` callback is executed. Returning true in the callback continues the visit
// to the child modules. Returning false makes the visit to continue in the sibling or the parent
// modules. This is used in check* functions below.
func (a *apexBundle) WalkPayloadDeps(ctx android.ModuleContext, do android.PayloadDepsCallback) {
ctx.WalkDeps(func(child, parent android.Module) bool {
am, ok := child.(android.ApexModule)
if !ok || !am.CanHaveApexVariants() {
return false
}
// Filter-out unwanted depedendencies
depTag := ctx.OtherModuleDependencyTag(child)
if _, ok := depTag.(android.ExcludeFromApexContentsTag); ok {
return false
}
if dt, ok := depTag.(*dependencyTag); ok && !dt.payload {
return false
}
ai, _ := android.OtherModuleProvider(ctx, child, android.ApexInfoProvider)
externalDep := !android.InList(ctx.ModuleName(), ai.InApexVariants)
// Visit actually
return do(ctx, parent, am, externalDep)
})
}
// filesystem type of the apex_payload.img inside the APEX. Currently, ext4 and f2fs are supported.
type fsType int
const (
ext4 fsType = iota
f2fs
erofs
)
func (f fsType) string() string {
switch f {
case ext4:
return ext4FsType
case f2fs:
return f2fsFsType
case erofs:
return erofsFsType
default:
panic(fmt.Errorf("unknown APEX payload type %d", f))
}
}
func (a *apexBundle) setCompression(ctx android.ModuleContext) {
if a.testOnlyShouldForceCompression() {
a.isCompressed = true
} else {
a.isCompressed = ctx.Config().ApexCompressionEnabled() && a.isCompressable()
}
}
func (a *apexBundle) setSystemLibLink(ctx android.ModuleContext) {
// Optimization. If we are building bundled APEX, for the files that are gathered due to the
// transitive dependencies, don't place them inside the APEX, but place a symlink pointing
// the same library in the system partition, thus effectively sharing the same libraries
// across the APEX boundary. For unbundled APEX, all the gathered files are actually placed
// in the APEX.
a.linkToSystemLib = !ctx.Config().UnbundledBuild() && a.installable()
// APEXes targeting other than system/system_ext partitions use vendor/product variants.
// So we can't link them to /system/lib libs which are core variants.
if a.SocSpecific() || a.DeviceSpecific() || (a.ProductSpecific() && ctx.Config().EnforceProductPartitionInterface()) {
a.linkToSystemLib = false
}
forced := ctx.Config().ForceApexSymlinkOptimization()
updatable := a.Updatable() || a.FutureUpdatable()
// We don't need the optimization for updatable APEXes, as it might give false signal
// to the system health when the APEXes are still bundled (b/149805758).
if !forced && updatable {
a.linkToSystemLib = false
}
}
func (a *apexBundle) setPayloadFsType(ctx android.ModuleContext) {
switch proptools.StringDefault(a.properties.Payload_fs_type, ext4FsType) {
case ext4FsType:
a.payloadFsType = ext4
case f2fsFsType:
a.payloadFsType = f2fs
case erofsFsType:
a.payloadFsType = erofs
default:
ctx.PropertyErrorf("payload_fs_type", "%q is not a valid filesystem for apex [ext4, f2fs, erofs]", *a.properties.Payload_fs_type)
}
}
func (a *apexBundle) isCompressable() bool {
return proptools.BoolDefault(a.overridableProperties.Compressible, false) && !a.testApex
}
func (a *apexBundle) commonBuildActions(ctx android.ModuleContext) bool {
a.checkApexAvailability(ctx)
a.checkUpdatable(ctx)
a.CheckMinSdkVersion(ctx)
a.checkStaticLinkingToStubLibraries(ctx)
a.checkStaticExecutables(ctx)
if len(a.properties.Tests) > 0 && !a.testApex {
ctx.PropertyErrorf("tests", "property allowed only in apex_test module type")
return false
}
return true
}
type visitorContext struct {
// all the files that will be included in this APEX
filesInfo []apexFile
// native lib dependencies
provideNativeLibs []string
requireNativeLibs []string
handleSpecialLibs bool
// if true, raise error on duplicate apexFile
checkDuplicate bool
// visitor skips these from this list of module names
unwantedTransitiveDeps []string
aconfigFiles []android.Path
}
func (vctx *visitorContext) normalizeFileInfo(mctx android.ModuleContext) {
encountered := make(map[string]apexFile)
for _, f := range vctx.filesInfo {
// Skips unwanted transitive deps. This happens, for example, with Rust binaries with prefer_rlib:true.
// TODO(b/295593640)
// Needs additional verification for the resulting APEX to ensure that skipped artifacts don't make problems.
// For example, DT_NEEDED modules should be found within the APEX unless they are marked in `requiredNativeLibs`.
if f.transitiveDep && f.module != nil && android.InList(mctx.OtherModuleName(f.module), vctx.unwantedTransitiveDeps) {
continue
}
dest := filepath.Join(f.installDir, f.builtFile.Base())
if e, ok := encountered[dest]; !ok {
encountered[dest] = f
} else {
if vctx.checkDuplicate && f.builtFile.String() != e.builtFile.String() {
mctx.ModuleErrorf("apex file %v is provided by two different files %v and %v",
dest, e.builtFile, f.builtFile)
return
}
// If a module is directly included and also transitively depended on
// consider it as directly included.
e.transitiveDep = e.transitiveDep && f.transitiveDep
// If a module is added as both a JNI library and a regular shared library, consider it as a
// JNI library.
e.isJniLib = e.isJniLib || f.isJniLib
encountered[dest] = e
}
}
vctx.filesInfo = vctx.filesInfo[:0]
for _, v := range encountered {
vctx.filesInfo = append(vctx.filesInfo, v)
}
sort.Slice(vctx.filesInfo, func(i, j int) bool {
// Sort by destination path so as to ensure consistent ordering even if the source of the files
// changes.
return vctx.filesInfo[i].path() < vctx.filesInfo[j].path()
})
}
func (a *apexBundle) depVisitor(vctx *visitorContext, ctx android.ModuleContext, child, parent blueprint.Module) bool {
depTag := ctx.OtherModuleDependencyTag(child)
if _, ok := depTag.(android.ExcludeFromApexContentsTag); ok {
return false
}
if mod, ok := child.(android.Module); ok && !mod.Enabled() {
return false
}
depName := ctx.OtherModuleName(child)
if _, isDirectDep := parent.(*apexBundle); isDirectDep {
switch depTag {
case sharedLibTag, jniLibTag:
isJniLib := depTag == jniLibTag
propertyName := "native_shared_libs"
if isJniLib {
propertyName = "jni_libs"
}
switch ch := child.(type) {
case *cc.Module:
if ch.IsStubs() {
ctx.PropertyErrorf(propertyName, "%q is a stub. Remove it from the list.", depName)
}
fi := apexFileForNativeLibrary(ctx, ch, vctx.handleSpecialLibs)
fi.isJniLib = isJniLib
vctx.filesInfo = append(vctx.filesInfo, fi)
addAconfigFiles(vctx, ctx, child)
// Collect the list of stub-providing libs except:
// - VNDK libs are only for vendors
// - bootstrap bionic libs are treated as provided by system
if ch.HasStubsVariants() && !a.vndkApex && !cc.InstallToBootstrap(ch.BaseModuleName(), ctx.Config()) {
vctx.provideNativeLibs = append(vctx.provideNativeLibs, fi.stem())
}
return true // track transitive dependencies
case *rust.Module:
fi := apexFileForRustLibrary(ctx, ch)
fi.isJniLib = isJniLib
vctx.filesInfo = append(vctx.filesInfo, fi)
addAconfigFiles(vctx, ctx, child)
return true // track transitive dependencies
default:
ctx.PropertyErrorf(propertyName, "%q is not a cc_library or cc_library_shared module", depName)
}
case executableTag:
switch ch := child.(type) {
case *cc.Module:
vctx.filesInfo = append(vctx.filesInfo, apexFileForExecutable(ctx, ch))
addAconfigFiles(vctx, ctx, child)
return true // track transitive dependencies
case *rust.Module:
vctx.filesInfo = append(vctx.filesInfo, apexFileForRustExecutable(ctx, ch))
addAconfigFiles(vctx, ctx, child)
return true // track transitive dependencies
default:
ctx.PropertyErrorf("binaries",
"%q is neither cc_binary, rust_binary, (embedded) py_binary, (host) blueprint_go_binary, nor (host) bootstrap_go_binary", depName)
}
case shBinaryTag:
if csh, ok := child.(*sh.ShBinary); ok {
vctx.filesInfo = append(vctx.filesInfo, apexFileForShBinary(ctx, csh))
} else {
ctx.PropertyErrorf("sh_binaries", "%q is not a sh_binary module", depName)
}
case bcpfTag:
_, ok := child.(*java.BootclasspathFragmentModule)
if !ok {
ctx.PropertyErrorf("bootclasspath_fragments", "%q is not a bootclasspath_fragment module", depName)
return false
}
vctx.filesInfo = append(vctx.filesInfo, apexBootclasspathFragmentFiles(ctx, child)...)
return true
case sscpfTag:
if _, ok := child.(*java.SystemServerClasspathModule); !ok {
ctx.PropertyErrorf("systemserverclasspath_fragments",
"%q is not a systemserverclasspath_fragment module", depName)
return false
}
if af := apexClasspathFragmentProtoFile(ctx, child); af != nil {
vctx.filesInfo = append(vctx.filesInfo, *af)
}
return true
case javaLibTag:
switch child.(type) {
case *java.Library, *java.SdkLibrary, *java.DexImport, *java.SdkLibraryImport, *java.Import:
af := apexFileForJavaModule(ctx, child.(javaModule))
if !af.ok() {
ctx.PropertyErrorf("java_libs", "%q is not configured to be compiled into dex", depName)
return false
}
vctx.filesInfo = append(vctx.filesInfo, af)
addAconfigFiles(vctx, ctx, child)
return true // track transitive dependencies
default:
ctx.PropertyErrorf("java_libs", "%q of type %q is not supported", depName, ctx.OtherModuleType(child))
}
case androidAppTag:
switch ap := child.(type) {
case *java.AndroidApp:
vctx.filesInfo = append(vctx.filesInfo, apexFilesForAndroidApp(ctx, ap)...)
addAconfigFiles(vctx, ctx, child)
return true // track transitive dependencies
case *java.AndroidAppImport:
vctx.filesInfo = append(vctx.filesInfo, apexFilesForAndroidApp(ctx, ap)...)
case *java.AndroidTestHelperApp:
vctx.filesInfo = append(vctx.filesInfo, apexFilesForAndroidApp(ctx, ap)...)
case *java.AndroidAppSet:
appDir := "app"
if ap.Privileged() {
appDir = "priv-app"
}
// TODO(b/224589412, b/226559955): Ensure that the dirname is
// suffixed so that PackageManager correctly invalidates the
// existing installed apk in favour of the new APK-in-APEX.
// See bugs for more information.
appDirName := filepath.Join(appDir, ap.BaseModuleName()+"@"+sanitizedBuildIdForPath(ctx))
af := newApexFile(ctx, ap.OutputFile(), ap.BaseModuleName(), appDirName, appSet, ap)
af.certificate = java.PresignedCertificate
vctx.filesInfo = append(vctx.filesInfo, af)
default:
ctx.PropertyErrorf("apps", "%q is not an android_app module", depName)
}
case rroTag:
if rro, ok := child.(java.RuntimeResourceOverlayModule); ok {
vctx.filesInfo = append(vctx.filesInfo, apexFileForRuntimeResourceOverlay(ctx, rro))
} else {
ctx.PropertyErrorf("rros", "%q is not an runtime_resource_overlay module", depName)
}
case bpfTag:
if bpfProgram, ok := child.(bpf.BpfModule); ok {
filesToCopy, _ := bpfProgram.OutputFiles("")
apex_sub_dir := bpfProgram.SubDir()
for _, bpfFile := range filesToCopy {
vctx.filesInfo = append(vctx.filesInfo, apexFileForBpfProgram(ctx, bpfFile, apex_sub_dir, bpfProgram))
}
} else {
ctx.PropertyErrorf("bpfs", "%q is not a bpf module", depName)
}
case fsTag:
if fs, ok := child.(filesystem.Filesystem); ok {
vctx.filesInfo = append(vctx.filesInfo, apexFileForFilesystem(ctx, fs.OutputPath(), fs))
} else {
ctx.PropertyErrorf("filesystems", "%q is not a filesystem module", depName)
}
case prebuiltTag:
if prebuilt, ok := child.(prebuilt_etc.PrebuiltEtcModule); ok {
vctx.filesInfo = append(vctx.filesInfo, apexFileForPrebuiltEtc(ctx, prebuilt, depName))
} else {
ctx.PropertyErrorf("prebuilts", "%q is not a prebuilt_etc module", depName)
}
case compatConfigTag:
if compatConfig, ok := child.(java.PlatformCompatConfigIntf); ok {
vctx.filesInfo = append(vctx.filesInfo, apexFileForCompatConfig(ctx, compatConfig, depName))
} else {
ctx.PropertyErrorf("compat_configs", "%q is not a platform_compat_config module", depName)
}
case testTag:
if ccTest, ok := child.(*cc.Module); ok {
if ccTest.IsTestPerSrcAllTestsVariation() {
// Multiple-output test module (where `test_per_src: true`).
//
// `ccTest` is the "" ("all tests") variation of a `test_per_src` module.
// We do not add this variation to `filesInfo`, as it has no output;
// however, we do add the other variations of this module as indirect
// dependencies (see below).
} else {
// Single-output test module (where `test_per_src: false`).
af := apexFileForExecutable(ctx, ccTest)
af.class = nativeTest
vctx.filesInfo = append(vctx.filesInfo, af)
}
return true // track transitive dependencies
} else {
ctx.PropertyErrorf("tests", "%q is not a cc module", depName)
}
case keyTag:
if key, ok := child.(*apexKey); ok {
a.privateKeyFile = key.privateKeyFile
a.publicKeyFile = key.publicKeyFile
} else {
ctx.PropertyErrorf("key", "%q is not an apex_key module", depName)
}
case certificateTag:
if dep, ok := child.(*java.AndroidAppCertificate); ok {
a.containerCertificateFile = dep.Certificate.Pem
a.containerPrivateKeyFile = dep.Certificate.Key
} else {
ctx.ModuleErrorf("certificate dependency %q must be an android_app_certificate module", depName)
}
}
return false
}
if a.vndkApex {
return false
}
// indirect dependencies
am, ok := child.(android.ApexModule)
if !ok {
return false
}
// We cannot use a switch statement on `depTag` here as the checked
// tags used below are private (e.g. `cc.sharedDepTag`).
if cc.IsSharedDepTag(depTag) || cc.IsRuntimeDepTag(depTag) {
if ch, ok := child.(*cc.Module); ok {
if ch.UseVndk() && a.useVndkAsStable(ctx) && ch.IsVndk() {
vctx.requireNativeLibs = append(vctx.requireNativeLibs, ":vndk")
return false
}
//TODO: b/296491928 Vendor APEX should use libbinder.ndk instead of libbinder once VNDK is fully deprecated.
if ch.UseVndk() && ctx.Config().IsVndkDeprecated() && child.Name() == "libbinder" {
return false
}
af := apexFileForNativeLibrary(ctx, ch, vctx.handleSpecialLibs)
af.transitiveDep = true
abInfo, _ := android.ModuleProvider(ctx, ApexBundleInfoProvider)
if !abInfo.Contents.DirectlyInApex(depName) && (ch.IsStubs() || ch.HasStubsVariants()) {
// If the dependency is a stubs lib, don't include it in this APEX,
// but make sure that the lib is installed on the device.
// In case no APEX is having the lib, the lib is installed to the system
// partition.
//
// Always include if we are a host-apex however since those won't have any
// system libraries.
//
// Skip the dependency in unbundled builds where the device image is not
// being built.
if ch.IsStubsImplementationRequired() && !am.DirectlyInAnyApex() && !ctx.Config().UnbundledBuild() {
// we need a module name for Make
name := ch.ImplementationModuleNameForMake(ctx) + ch.Properties.SubName
if !android.InList(name, a.makeModulesToInstall) {
a.makeModulesToInstall = append(a.makeModulesToInstall, name)
}
}
vctx.requireNativeLibs = append(vctx.requireNativeLibs, af.stem())
// Don't track further
return false
}
// If the dep is not considered to be in the same
// apex, don't add it to filesInfo so that it is not
// included in this APEX.
// TODO(jiyong): move this to at the top of the
// else-if clause for the indirect dependencies.
// Currently, that's impossible because we would
// like to record requiredNativeLibs even when
// DepIsInSameAPex is false. We also shouldn't do
// this for host.
//
// TODO(jiyong): explain why the same module is passed in twice.
// Switching the first am to parent breaks lots of tests.
if !android.IsDepInSameApex(ctx, am, am) {
return false
}
vctx.filesInfo = append(vctx.filesInfo, af)
return true // track transitive dependencies
} else if rm, ok := child.(*rust.Module); ok {
af := apexFileForRustLibrary(ctx, rm)
af.transitiveDep = true
vctx.filesInfo = append(vctx.filesInfo, af)
return true // track transitive dependencies
}
} else if cc.IsTestPerSrcDepTag(depTag) {
if ch, ok := child.(*cc.Module); ok {
af := apexFileForExecutable(ctx, ch)
// Handle modules created as `test_per_src` variations of a single test module:
// use the name of the generated test binary (`fileToCopy`) instead of the name
// of the original test module (`depName`, shared by all `test_per_src`
// variations of that module).
af.androidMkModuleName = filepath.Base(af.builtFile.String())
// these are not considered transitive dep
af.transitiveDep = false
vctx.filesInfo = append(vctx.filesInfo, af)
return true // track transitive dependencies
}
} else if cc.IsHeaderDepTag(depTag) {
// nothing
} else if java.IsJniDepTag(depTag) {
// Because APK-in-APEX embeds jni_libs transitively, we don't need to track transitive deps
} else if java.IsXmlPermissionsFileDepTag(depTag) {
if prebuilt, ok := child.(prebuilt_etc.PrebuiltEtcModule); ok {
vctx.filesInfo = append(vctx.filesInfo, apexFileForPrebuiltEtc(ctx, prebuilt, depName))
}
} else if rust.IsDylibDepTag(depTag) {
if rustm, ok := child.(*rust.Module); ok && rustm.IsInstallableToApex() {
af := apexFileForRustLibrary(ctx, rustm)
af.transitiveDep = true
vctx.filesInfo = append(vctx.filesInfo, af)
return true // track transitive dependencies
}
} else if rust.IsRlibDepTag(depTag) {
// Rlib is statically linked, but it might have shared lib
// dependencies. Track them.
return true
} else if java.IsBootclasspathFragmentContentDepTag(depTag) {
// Add the contents of the bootclasspath fragment to the apex.
switch child.(type) {
case *java.Library, *java.SdkLibrary:
javaModule := child.(javaModule)
af := apexFileForBootclasspathFragmentContentModule(ctx, parent, javaModule)
if !af.ok() {
ctx.PropertyErrorf("bootclasspath_fragments",
"bootclasspath_fragment content %q is not configured to be compiled into dex", depName)
return false
}
vctx.filesInfo = append(vctx.filesInfo, af)
return true // track transitive dependencies
default:
ctx.PropertyErrorf("bootclasspath_fragments",
"bootclasspath_fragment content %q of type %q is not supported", depName, ctx.OtherModuleType(child))
}
} else if java.IsSystemServerClasspathFragmentContentDepTag(depTag) {
// Add the contents of the systemserverclasspath fragment to the apex.
switch child.(type) {
case *java.Library, *java.SdkLibrary:
af := apexFileForJavaModule(ctx, child.(javaModule))
vctx.filesInfo = append(vctx.filesInfo, af)
if profileAf := apexFileForJavaModuleProfile(ctx, child.(javaModule)); profileAf != nil {
vctx.filesInfo = append(vctx.filesInfo, *profileAf)
}
return true // track transitive dependencies
default:
ctx.PropertyErrorf("systemserverclasspath_fragments",
"systemserverclasspath_fragment content %q of type %q is not supported", depName, ctx.OtherModuleType(child))
}
} else if _, ok := depTag.(android.CopyDirectlyInAnyApexTag); ok {
// nothing
} else if depTag == android.DarwinUniversalVariantTag {
// nothing
} else if am.CanHaveApexVariants() && am.IsInstallableToApex() {
ctx.ModuleErrorf("unexpected tag %s for indirect dependency %q", android.PrettyPrintTag(depTag), depName)
}
return false
}
func addAconfigFiles(vctx *visitorContext, ctx android.ModuleContext, module blueprint.Module) {
dep, _ := android.OtherModuleProvider(ctx, module, android.AconfigTransitiveDeclarationsInfoProvider)
if len(dep.AconfigFiles) > 0 && dep.AconfigFiles[ctx.ModuleName()] != nil {
vctx.aconfigFiles = append(vctx.aconfigFiles, dep.AconfigFiles[ctx.ModuleName()]...)
}
}
func (a *apexBundle) shouldCheckDuplicate(ctx android.ModuleContext) bool {
// TODO(b/263308293) remove this
if a.properties.IsCoverageVariant {
return false
}
if ctx.DeviceConfig().DeviceArch() == "" {
return false
}
return true
}
// Creates build rules for an APEX. It consists of the following major steps:
//
// 1) do some validity checks such as apex_available, min_sdk_version, etc.
// 2) traverse the dependency tree to collect apexFile structs from them.
// 3) some fields in apexBundle struct are configured
// 4) generate the build rules to create the APEX. This is mostly done in builder.go.
func (a *apexBundle) GenerateAndroidBuildActions(ctx android.ModuleContext) {
////////////////////////////////////////////////////////////////////////////////////////////
// 1) do some validity checks such as apex_available, min_sdk_version, etc.
if !a.commonBuildActions(ctx) {
return
}
////////////////////////////////////////////////////////////////////////////////////////////
// 2) traverse the dependency tree to collect apexFile structs from them.
// TODO(jiyong): do this using WalkPayloadDeps
// TODO(jiyong): make this clean!!!
vctx := visitorContext{
handleSpecialLibs: !android.Bool(a.properties.Ignore_system_library_special_case),
checkDuplicate: a.shouldCheckDuplicate(ctx),
unwantedTransitiveDeps: a.properties.Unwanted_transitive_deps,
}
ctx.WalkDepsBlueprint(func(child, parent blueprint.Module) bool { return a.depVisitor(&vctx, ctx, child, parent) })
vctx.normalizeFileInfo(ctx)
if a.privateKeyFile == nil {
if ctx.Config().AllowMissingDependencies() {
// TODO(b/266099037): a better approach for slim manifests.
ctx.AddMissingDependencies([]string{String(a.overridableProperties.Key)})
// Create placeholder paths for later stages that expect to see those paths,
// though they won't be used.
var unusedPath = android.PathForModuleOut(ctx, "nonexistentprivatekey")
ctx.Build(pctx, android.BuildParams{
Rule: android.ErrorRule,
Output: unusedPath,
Args: map[string]string{
"error": "Private key not available",
},
})
a.privateKeyFile = unusedPath
} else {
ctx.PropertyErrorf("key", "private_key for %q could not be found", String(a.overridableProperties.Key))
return
}
}
if a.publicKeyFile == nil {
if ctx.Config().AllowMissingDependencies() {
// TODO(b/266099037): a better approach for slim manifests.
ctx.AddMissingDependencies([]string{String(a.overridableProperties.Key)})
// Create placeholder paths for later stages that expect to see those paths,
// though they won't be used.
var unusedPath = android.PathForModuleOut(ctx, "nonexistentpublickey")
ctx.Build(pctx, android.BuildParams{
Rule: android.ErrorRule,
Output: unusedPath,
Args: map[string]string{
"error": "Public key not available",
},
})
a.publicKeyFile = unusedPath
} else {
ctx.PropertyErrorf("key", "public_key for %q could not be found", String(a.overridableProperties.Key))
return
}
}
////////////////////////////////////////////////////////////////////////////////////////////
// 3) some fields in apexBundle struct are configured
a.installDir = android.PathForModuleInstall(ctx, "apex")
a.filesInfo = vctx.filesInfo
a.aconfigFiles = android.FirstUniquePaths(vctx.aconfigFiles)
a.setPayloadFsType(ctx)
a.setSystemLibLink(ctx)
a.compatSymlinks = makeCompatSymlinks(a.BaseModuleName(), ctx)
////////////////////////////////////////////////////////////////////////////////////////////
// 4) generate the build rules to create the APEX. This is done in builder.go.
a.buildManifest(ctx, vctx.provideNativeLibs, vctx.requireNativeLibs)
a.buildApex(ctx)
a.buildApexDependencyInfo(ctx)
a.buildLintReports(ctx)
// Set a provider for dexpreopt of bootjars
a.provideApexExportsInfo(ctx)
}
// Set a provider containing information about the jars and .prof provided by the apex
// Apexes built from source retrieve this information by visiting `bootclasspath_fragments`
// Used by dex_bootjars to generate the boot image
func (a *apexBundle) provideApexExportsInfo(ctx android.ModuleContext) {
ctx.VisitDirectDepsWithTag(bcpfTag, func(child android.Module) {
if info, ok := android.OtherModuleProvider(ctx, child, java.BootclasspathFragmentApexContentInfoProvider); ok {
exports := android.ApexExportsInfo{
ApexName: a.ApexVariationName(),
ProfilePathOnHost: info.ProfilePathOnHost(),
LibraryNameToDexJarPathOnHost: info.DexBootJarPathMap(),
}
android.SetProvider(ctx, android.ApexExportsInfoProvider, exports)
}
})
}
// apexBootclasspathFragmentFiles returns the list of apexFile structures defining the files that
// the bootclasspath_fragment contributes to the apex.
func apexBootclasspathFragmentFiles(ctx android.ModuleContext, module blueprint.Module) []apexFile {
bootclasspathFragmentInfo, _ := android.OtherModuleProvider(ctx, module, java.BootclasspathFragmentApexContentInfoProvider)
var filesToAdd []apexFile
// Add classpaths.proto config.
if af := apexClasspathFragmentProtoFile(ctx, module); af != nil {
filesToAdd = append(filesToAdd, *af)
}
pathInApex := bootclasspathFragmentInfo.ProfileInstallPathInApex()
if pathInApex != "" {
pathOnHost := bootclasspathFragmentInfo.ProfilePathOnHost()
tempPath := android.PathForModuleOut(ctx, "boot_image_profile", pathInApex)
if pathOnHost != nil {
// We need to copy the profile to a temporary path with the right filename because the apexer
// will take the filename as is.
ctx.Build(pctx, android.BuildParams{
Rule: android.Cp,
Input: pathOnHost,
Output: tempPath,
})
} else {
// At this point, the boot image profile cannot be generated. It is probably because the boot
// image profile source file does not exist on the branch, or it is not available for the
// current build target.
// However, we cannot enforce the boot image profile to be generated because some build
// targets (such as module SDK) do not need it. It is only needed when the APEX is being
// built. Therefore, we create an error rule so that an error will occur at the ninja phase
// only if the APEX is being built.
ctx.Build(pctx, android.BuildParams{
Rule: android.ErrorRule,
Output: tempPath,
Args: map[string]string{
"error": "Boot image profile cannot be generated",
},
})
}
androidMkModuleName := filepath.Base(pathInApex)
af := newApexFile(ctx, tempPath, androidMkModuleName, filepath.Dir(pathInApex), etc, nil)
filesToAdd = append(filesToAdd, af)
}
return filesToAdd
}
// apexClasspathFragmentProtoFile returns *apexFile structure defining the classpath.proto config that
// the module contributes to the apex; or nil if the proto config was not generated.
func apexClasspathFragmentProtoFile(ctx android.ModuleContext, module blueprint.Module) *apexFile {
info, _ := android.OtherModuleProvider(ctx, module, java.ClasspathFragmentProtoContentInfoProvider)
if !info.ClasspathFragmentProtoGenerated {
return nil
}
classpathProtoOutput := info.ClasspathFragmentProtoOutput
af := newApexFile(ctx, classpathProtoOutput, classpathProtoOutput.Base(), info.ClasspathFragmentProtoInstallDir.Rel(), etc, nil)
return &af
}
// apexFileForBootclasspathFragmentContentModule creates an apexFile for a bootclasspath_fragment
// content module, i.e. a library that is part of the bootclasspath.
func apexFileForBootclasspathFragmentContentModule(ctx android.ModuleContext, fragmentModule blueprint.Module, javaModule javaModule) apexFile {
bootclasspathFragmentInfo, _ := android.OtherModuleProvider(ctx, fragmentModule, java.BootclasspathFragmentApexContentInfoProvider)
// Get the dexBootJar from the bootclasspath_fragment as that is responsible for performing the
// hidden API encpding.
dexBootJar, err := bootclasspathFragmentInfo.DexBootJarPathForContentModule(javaModule)
if err != nil {
ctx.ModuleErrorf("%s", err)
}
// Create an apexFile as for a normal java module but with the dex boot jar provided by the
// bootclasspath_fragment.
af := apexFileForJavaModuleWithFile(ctx, javaModule, dexBootJar)
return af
}
///////////////////////////////////////////////////////////////////////////////////////////////////
// Factory functions
//
func newApexBundle() *apexBundle {
module := &apexBundle{}
module.AddProperties(&module.properties)
module.AddProperties(&module.targetProperties)
module.AddProperties(&module.archProperties)
module.AddProperties(&module.overridableProperties)
android.InitAndroidMultiTargetsArchModule(module, android.DeviceSupported, android.MultilibCommon)
android.InitDefaultableModule(module)
android.InitOverridableModule(module, &module.overridableProperties.Overrides)
multitree.InitExportableModule(module)
return module
}
func ApexBundleFactory(testApex bool) android.Module {
bundle := newApexBundle()
bundle.testApex = testApex
return bundle
}
// apex_test is an APEX for testing. The difference from the ordinary apex module type is that
// certain compatibility checks such as apex_available are not done for apex_test.
func TestApexBundleFactory() android.Module {
bundle := newApexBundle()
bundle.testApex = true
return bundle
}
// apex packages other modules into an APEX file which is a packaging format for system-level
// components like binaries, shared libraries, etc.
func BundleFactory() android.Module {
return newApexBundle()
}
type Defaults struct {
android.ModuleBase
android.DefaultsModuleBase
}
// apex_defaults provides defaultable properties to other apex modules.
func DefaultsFactory() android.Module {
module := &Defaults{}
module.AddProperties(
&apexBundleProperties{},
&apexTargetBundleProperties{},
&apexArchBundleProperties{},
&overridableProperties{},
)
android.InitDefaultsModule(module)
return module
}
type OverrideApex struct {
android.ModuleBase
android.OverrideModuleBase
}
func (o *OverrideApex) GenerateAndroidBuildActions(_ android.ModuleContext) {
// All the overrides happen in the base module.
}
// override_apex is used to create an apex module based on another apex module by overriding some of
// its properties.
func OverrideApexFactory() android.Module {
m := &OverrideApex{}
m.AddProperties(&overridableProperties{})
android.InitAndroidMultiTargetsArchModule(m, android.DeviceSupported, android.MultilibCommon)
android.InitOverrideModule(m)
return m
}
///////////////////////////////////////////////////////////////////////////////////////////////////
// Vality check routines
//
// These are called in at the very beginning of GenerateAndroidBuildActions to flag an error when
// certain conditions are not met.
//
// TODO(jiyong): move these checks to a separate go file.
var _ android.ModuleWithMinSdkVersionCheck = (*apexBundle)(nil)
// Ensures that min_sdk_version of the included modules are equal or less than the min_sdk_version
// of this apexBundle.
func (a *apexBundle) CheckMinSdkVersion(ctx android.ModuleContext) {
if a.testApex || a.vndkApex {
return
}
// apexBundle::minSdkVersion reports its own errors.
minSdkVersion := a.minSdkVersion(ctx)
android.CheckMinSdkVersion(ctx, minSdkVersion, a.WalkPayloadDeps)
}
// Returns apex's min_sdk_version string value, honoring overrides
func (a *apexBundle) minSdkVersionValue(ctx android.EarlyModuleContext) string {
// Only override the minSdkVersion value on Apexes which already specify
// a min_sdk_version (it's optional for non-updatable apexes), and that its
// min_sdk_version value is lower than the one to override with.
minApiLevel := android.MinSdkVersionFromValue(ctx, proptools.String(a.properties.Min_sdk_version))
if minApiLevel.IsNone() {
return ""
}
overrideMinSdkValue := ctx.DeviceConfig().ApexGlobalMinSdkVersionOverride()
overrideApiLevel := android.MinSdkVersionFromValue(ctx, overrideMinSdkValue)
if !overrideApiLevel.IsNone() && overrideApiLevel.CompareTo(minApiLevel) > 0 {
minApiLevel = overrideApiLevel
}
return minApiLevel.String()
}
// Returns apex's min_sdk_version SdkSpec, honoring overrides
func (a *apexBundle) MinSdkVersion(ctx android.EarlyModuleContext) android.ApiLevel {
return a.minSdkVersion(ctx)
}
// Returns apex's min_sdk_version ApiLevel, honoring overrides
func (a *apexBundle) minSdkVersion(ctx android.EarlyModuleContext) android.ApiLevel {
return android.MinSdkVersionFromValue(ctx, a.minSdkVersionValue(ctx))
}
// Ensures that a lib providing stub isn't statically linked
func (a *apexBundle) checkStaticLinkingToStubLibraries(ctx android.ModuleContext) {
// Practically, we only care about regular APEXes on the device.
if a.testApex || a.vndkApex {
return
}
abInfo, _ := android.ModuleProvider(ctx, ApexBundleInfoProvider)
a.WalkPayloadDeps(ctx, func(ctx android.ModuleContext, from blueprint.Module, to android.ApexModule, externalDep bool) bool {
if ccm, ok := to.(*cc.Module); ok {
apexName := ctx.ModuleName()
fromName := ctx.OtherModuleName(from)
toName := ctx.OtherModuleName(to)
// If `to` is not actually in the same APEX as `from` then it does not need
// apex_available and neither do any of its dependencies.
//
// It is ok to call DepIsInSameApex() directly from within WalkPayloadDeps().
if am, ok := from.(android.DepIsInSameApex); ok && !am.DepIsInSameApex(ctx, to) {
// As soon as the dependency graph crosses the APEX boundary, don't go further.
return false
}
// The dynamic linker and crash_dump tool in the runtime APEX is the only
// exception to this rule. It can't make the static dependencies dynamic
// because it can't do the dynamic linking for itself.
// Same rule should be applied to linkerconfig, because it should be executed
// only with static linked libraries before linker is available with ld.config.txt
if apexName == "com.android.runtime" && (fromName == "linker" || fromName == "crash_dump" || fromName == "linkerconfig") {
return false
}
isStubLibraryFromOtherApex := ccm.HasStubsVariants() && !abInfo.Contents.DirectlyInApex(toName)
if isStubLibraryFromOtherApex && !externalDep {
ctx.ModuleErrorf("%q required by %q is a native library providing stub. "+
"It shouldn't be included in this APEX via static linking. Dependency path: %s", to.String(), fromName, ctx.GetPathString(false))
}
}
return true
})
}
// checkUpdatable enforces APEX and its transitive dep properties to have desired values for updatable APEXes.
func (a *apexBundle) checkUpdatable(ctx android.ModuleContext) {
if a.Updatable() {
if a.minSdkVersionValue(ctx) == "" {
ctx.PropertyErrorf("updatable", "updatable APEXes should set min_sdk_version as well")
}
if a.UsePlatformApis() {
ctx.PropertyErrorf("updatable", "updatable APEXes can't use platform APIs")
}
if proptools.Bool(a.properties.Use_vndk_as_stable) {
ctx.PropertyErrorf("use_vndk_as_stable", "updatable APEXes can't use external VNDK libs")
}
if a.FutureUpdatable() {
ctx.PropertyErrorf("future_updatable", "Already updatable. Remove `future_updatable: true:`")
}
a.checkJavaStableSdkVersion(ctx)
a.checkClasspathFragments(ctx)
}
}
// checkClasspathFragments enforces that all classpath fragments in deps generate classpaths.proto config.
func (a *apexBundle) checkClasspathFragments(ctx android.ModuleContext) {
ctx.VisitDirectDeps(func(module android.Module) {
if tag := ctx.OtherModuleDependencyTag(module); tag == bcpfTag || tag == sscpfTag {
info, _ := android.OtherModuleProvider(ctx, module, java.ClasspathFragmentProtoContentInfoProvider)
if !info.ClasspathFragmentProtoGenerated {
ctx.OtherModuleErrorf(module, "is included in updatable apex %v, it must not set generate_classpaths_proto to false", ctx.ModuleName())
}
}
})
}
// checkJavaStableSdkVersion enforces that all Java deps are using stable SDKs to compile.
func (a *apexBundle) checkJavaStableSdkVersion(ctx android.ModuleContext) {
// Visit direct deps only. As long as we guarantee top-level deps are using stable SDKs,
// java's checkLinkType guarantees correct usage for transitive deps
ctx.VisitDirectDepsBlueprint(func(module blueprint.Module) {
tag := ctx.OtherModuleDependencyTag(module)
switch tag {
case javaLibTag, androidAppTag:
if m, ok := module.(interface {
CheckStableSdkVersion(ctx android.BaseModuleContext) error
}); ok {
if err := m.CheckStableSdkVersion(ctx); err != nil {
ctx.ModuleErrorf("cannot depend on \"%v\": %v", ctx.OtherModuleName(module), err)
}
}
}
})
}
// checkApexAvailability ensures that the all the dependencies are marked as available for this APEX.
func (a *apexBundle) checkApexAvailability(ctx android.ModuleContext) {
// Let's be practical. Availability for test, host, and the VNDK apex isn't important
if a.testApex || a.vndkApex {
return
}
// Because APEXes targeting other than system/system_ext partitions can't set
// apex_available, we skip checks for these APEXes
if a.SocSpecific() || a.DeviceSpecific() || (a.ProductSpecific() && ctx.Config().EnforceProductPartitionInterface()) {
return
}
// Coverage build adds additional dependencies for the coverage-only runtime libraries.
// Requiring them and their transitive depencies with apex_available is not right
// because they just add noise.
if ctx.Config().IsEnvTrue("EMMA_INSTRUMENT") || a.IsNativeCoverageNeeded(ctx) {
return
}
a.WalkPayloadDeps(ctx, func(ctx android.ModuleContext, from blueprint.Module, to android.ApexModule, externalDep bool) bool {
// As soon as the dependency graph crosses the APEX boundary, don't go further.
if externalDep {
return false
}
apexName := ctx.ModuleName()
for _, props := range ctx.Module().GetProperties() {
if apexProps, ok := props.(*apexBundleProperties); ok {
if apexProps.Apex_available_name != nil {
apexName = *apexProps.Apex_available_name
}
}
}
fromName := ctx.OtherModuleName(from)
toName := ctx.OtherModuleName(to)
// If `to` is not actually in the same APEX as `from` then it does not need
// apex_available and neither do any of its dependencies.
//
// It is ok to call DepIsInSameApex() directly from within WalkPayloadDeps().
if am, ok := from.(android.DepIsInSameApex); ok && !am.DepIsInSameApex(ctx, to) {
// As soon as the dependency graph crosses the APEX boundary, don't go
// further.
return false
}
if to.AvailableFor(apexName) || baselineApexAvailable(apexName, toName) {
return true
}
Friendly error message on apex_available and min_sdk_version checks 1) suggest a fix at the end of the message 2) add new lines around the dependency path so that they are visually separated from rest of the error message Bug: N/A Test: m with an intentional break error: bionic/apex/Android.bp:32:1: module "com.android.runtime" variant "android_common_com.android.runtime_image": "libutils_headers" requires "libsystem_headers" that doesn't list the APEX under 'apex_available'. Dependency path: via tag apex.dependencyTag: { name:executable payload:true} -> crash_dump{os:android,image:,arch:arm_armv8-a,sdk:,apex:apex10000} via tag cc.libraryDependencyTag: { Kind:staticLibraryDependency Order:normalLibraryDependency wholeStatic:false reexportFlags:false explicitlyVersioned:false dataLib:false ndk:false staticUnwinder:false makeSuffix: skipApexAllowedDependenciesCheck:false excludeInApex:false} -> libtombstoned_client_static{os:android,image:,arch:arm_armv8-a,sdk:,link:static,apex:apex10000} via tag cc.libraryDependencyTag: { Kind:staticLibraryDependency Order:normalLibraryDependency wholeStatic:true reexportFlags:true explicitlyVersioned:false dataLib:false ndk:false staticUnwinder:false makeSuffix: skipApexAllowedDependenciesCheck:false excludeInApex:false} -> libcutils{os:android,image:,arch:arm_armv8-a,sdk:,link:static,asan:,apex:apex10000} via tag cc.libraryDependencyTag: { Kind:headerLibraryDependency Order:normalLibraryDependency wholeStatic:false reexportFlags:false explicitlyVersioned:false dataLib:false ndk:false staticUnwinder:false makeSuffix: skipApexAllowedDependenciesCheck:false excludeInApex:false} -> libutils_headers{os:android,image:,arch:arm_armv8-a,sdk:,asan:,apex:apex10000} via tag cc.libraryDependencyTag: { Kind:headerLibraryDependency Order:normalLibraryDependency wholeStatic:false reexportFlags:true explicitlyVersioned:false dataLib:false ndk:false staticUnwinder:false makeSuffix: skipApexAllowedDependenciesCheck:false excludeInApex:false} -> libsystem_headers{os:android,image:,arch:arm_armv8-a,sdk:,asan:,apex:apex10000} Consider adding "com.android.runtime" to 'apex_available' property of "libsystem_headers" Change-Id: I09f92c3086ea433780133a33ba0ad73baee6dc41
2021-03-04 05:03:10 +01:00
ctx.ModuleErrorf("%q requires %q that doesn't list the APEX under 'apex_available'."+
"\n\nDependency path:%s\n\n"+
"Consider adding %q to 'apex_available' property of %q",
fromName, toName, ctx.GetPathString(true), apexName, toName)
// Visit this module's dependencies to check and report any issues with their availability.
return true
})
}
// checkStaticExecutable ensures that executables in an APEX are not static.
func (a *apexBundle) checkStaticExecutables(ctx android.ModuleContext) {
ctx.VisitDirectDepsBlueprint(func(module blueprint.Module) {
if ctx.OtherModuleDependencyTag(module) != executableTag {
return
}
if l, ok := module.(cc.LinkableInterface); ok && l.StaticExecutable() {
apex := a.ApexVariationName()
exec := ctx.OtherModuleName(module)
if isStaticExecutableAllowed(apex, exec) {
return
}
ctx.ModuleErrorf("executable %s is static", ctx.OtherModuleName(module))
}
})
}
// A small list of exceptions where static executables are allowed in APEXes.
func isStaticExecutableAllowed(apex string, exec string) bool {
m := map[string][]string{
"com.android.runtime": {
"linker",
"linkerconfig",
},
}
execNames, ok := m[apex]
return ok && android.InList(exec, execNames)
}
// Collect information for opening IDE project files in java/jdeps.go.
func (a *apexBundle) IDEInfo(dpInfo *android.IdeInfo) {
dpInfo.Deps = append(dpInfo.Deps, a.properties.Java_libs...)
dpInfo.Deps = append(dpInfo.Deps, a.properties.Bootclasspath_fragments...)
dpInfo.Deps = append(dpInfo.Deps, a.properties.Systemserverclasspath_fragments...)
}
var (
apexAvailBaseline = makeApexAvailableBaseline()
inverseApexAvailBaseline = invertApexBaseline(apexAvailBaseline)
)
func baselineApexAvailable(apex, moduleName string) bool {
key := apex
moduleName = normalizeModuleName(moduleName)
if val, ok := apexAvailBaseline[key]; ok && android.InList(moduleName, val) {
return true
}
key = android.AvailableToAnyApex
if val, ok := apexAvailBaseline[key]; ok && android.InList(moduleName, val) {
return true
}
return false
}
func normalizeModuleName(moduleName string) string {
// Prebuilt modules (e.g. java_import, etc.) have "prebuilt_" prefix added by the build
// system. Trim the prefix for the check since they are confusing
moduleName = android.RemoveOptionalPrebuiltPrefix(moduleName)
if strings.HasPrefix(moduleName, "libclang_rt.") {
// This module has many arch variants that depend on the product being built.
// We don't want to list them all
moduleName = "libclang_rt"
}
if strings.HasPrefix(moduleName, "androidx.") {
// TODO(b/156996905) Set apex_available/min_sdk_version for androidx support libraries
moduleName = "androidx"
}
return moduleName
}
// Transform the map of apex -> modules to module -> apexes.
func invertApexBaseline(m map[string][]string) map[string][]string {
r := make(map[string][]string)
for apex, modules := range m {
for _, module := range modules {
r[module] = append(r[module], apex)
}
}
return r
}
// Retrieve the baseline of apexes to which the supplied module belongs.
func BaselineApexAvailable(moduleName string) []string {
return inverseApexAvailBaseline[normalizeModuleName(moduleName)]
}
// This is a map from apex to modules, which overrides the apex_available setting for that
// particular module to make it available for the apex regardless of its setting.
// TODO(b/147364041): remove this
func makeApexAvailableBaseline() map[string][]string {
// The "Module separator"s below are employed to minimize merge conflicts.
m := make(map[string][]string)
//
// Module separator
//
m["com.android.mediaprovider"] = []string{
"MediaProvider",
"MediaProviderGoogle",
"fmtlib_ndk",
"libbase_ndk",
"libfuse",
"libfuse_jni",
}
//
// Module separator
//
m["com.android.runtime"] = []string{
"libdebuggerd",
"libdebuggerd_common_headers",
"libdebuggerd_handler_core",
"libdl_static",
"libjemalloc5",
"liblinker_main",
"liblinker_malloc",
"liblzma",
"libprocinfo",
"libpropertyinfoparser",
"libscudo",
"libsystemproperties",
"libtombstoned_client_static",
"libunwindstack",
"libz",
"libziparchive",
}
//
// Module separator
//
m["com.android.tethering"] = []string{
"android.hardware.tetheroffload.config-V1.0-java",
"android.hardware.tetheroffload.control-V1.0-java",
"net-utils-framework-common",
}
//
// Module separator
//
m["com.android.wifi"] = []string{
"PlatformProperties",
"android.hardware.wifi-V1.0-java",
"android.hardware.wifi-V1.0-java-constants",
"android.hardware.wifi-V1.1-java",
"android.hardware.wifi-V1.2-java",
"android.hardware.wifi-V1.3-java",
"android.hardware.wifi-V1.4-java",
"android.hardware.wifi.hostapd-V1.0-java",
"android.hardware.wifi.hostapd-V1.1-java",
"android.hardware.wifi.hostapd-V1.2-java",
"android.hardware.wifi.supplicant-V1.0-java",
"android.hardware.wifi.supplicant-V1.1-java",
"android.hardware.wifi.supplicant-V1.2-java",
"android.hardware.wifi.supplicant-V1.3-java",
"bouncycastle-unbundled",
"framework-wifi-util-lib",
"ksoap2",
"libnanohttpd",
"wifi-lite-protos",
"wifi-nano-protos",
"wifi-service-pre-jarjar",
}
//
// Module separator
//
m[android.AvailableToAnyApex] = []string{
"libprofile-clang-extras",
"libprofile-clang-extras_ndk",
"libprofile-extras",
"libprofile-extras_ndk",
}
return m
}
func init() {
android.AddNeverAllowRules(createBcpPermittedPackagesRules(qBcpPackages())...)
android.AddNeverAllowRules(createBcpPermittedPackagesRules(rBcpPackages())...)
}
func createBcpPermittedPackagesRules(bcpPermittedPackages map[string][]string) []android.Rule {
rules := make([]android.Rule, 0, len(bcpPermittedPackages))
for jar, permittedPackages := range bcpPermittedPackages {
permittedPackagesRule := android.NeverAllow().
With("name", jar).
WithMatcher("permitted_packages", android.NotInList(permittedPackages)).
Because(jar +
" bootjar may only use these package prefixes: " + strings.Join(permittedPackages, ",") +
". Please consider the following alternatives:\n" +
" 1. If the offending code is from a statically linked library, consider " +
"removing that dependency and using an alternative already in the " +
"bootclasspath, or perhaps a shared library." +
" 2. Move the offending code into an allowed package.\n" +
" 3. Jarjar the offending code. Please be mindful of the potential system " +
"health implications of bundling that code, particularly if the offending jar " +
"is part of the bootclasspath.")
rules = append(rules, permittedPackagesRule)
}
return rules
}
// DO NOT EDIT! These are the package prefixes that are exempted from being AOT'ed by ART.
// Adding code to the bootclasspath in new packages will cause issues on module update.
func qBcpPackages() map[string][]string {
return map[string][]string{
"conscrypt": {
"android.net.ssl",
"com.android.org.conscrypt",
},
"updatable-media": {
"android.media",
},
}
}
// DO NOT EDIT! These are the package prefixes that are exempted from being AOT'ed by ART.
// Adding code to the bootclasspath in new packages will cause issues on module update.
func rBcpPackages() map[string][]string {
return map[string][]string{
"framework-mediaprovider": {
"android.provider",
},
"framework-permission": {
"android.permission",
"android.app.role",
"com.android.permission",
"com.android.role",
},
"framework-sdkextensions": {
"android.os.ext",
},
"framework-statsd": {
"android.app",
"android.os",
"android.util",
"com.android.internal.statsd",
"com.android.server.stats",
},
"framework-wifi": {
"com.android.server.wifi",
"com.android.wifi.x",
"android.hardware.wifi",
"android.net.wifi",
},
"framework-tethering": {
"android.net",
},
}
}
func (a *apexBundle) IsTestApex() bool {
return a.testApex
}
func (a *apexBundle) useVndkAsStable(ctx android.BaseModuleContext) bool {
// VNDK cannot be linked if it is deprecated
if ctx.Config().IsVndkDeprecated() {
return false
}
return proptools.Bool(a.properties.Use_vndk_as_stable)
}